JP2021059311A - Tire/wheel assembly - Google Patents

Abstract

To provide a tire/wheel assembly capable of improving hydro-planing performance during linear traveling of a tire while securing wear resistance of the tire.SOLUTION: A tire/wheel assembly includes a tire having a tread part, and a wheel having a rim part. The tire is fitted to the rim part, and the tire/wheel assembly is provided with a power incoming coil. A tread 13a of the tread part has one or more circumferential main grooves 17 extending in a tire circumferential direction. A negative ratio of a half part of the circumferential main grooves in one tire width direction of the tread of the tread part to become an inside when fitted to the vehicle is larger than a negative ratio of a half part of the circumferential main grooves in the other tire width direction of the tread of the tread part to become an outside when fitted to the vehicle.SELECTED DRAWING: Figure 5

Description

The present invention relates to a tire / wheel assembly.

In recent years, electric vehicles have been actively developed as vehicles that use electric energy as power (for example, Patent Document 1). In particular, in the autonomous driving technology that is being put into practical use in earnest, the development of the autonomous driving technology using an electric vehicle is proceeding because the response to the vehicle operation is better when the electric motor is used than when the engine is used. Has been done.

As a power supply system for supplying power to the power receiving device included in the tire / wheel assembly, an overhead wire system which is a wired system, an electromagnetic induction system which is a wireless system, an electric field coupling system, and the like have been proposed.

Japanese Unexamined Patent Publication No. 2018-088077

Among them, the electromagnetic induction method causes a magnetic flux to be generated in a direction perpendicular to the road surface by passing a current through a transmission coil (primary coil) installed on the road surface side, and the magnetic flux is generated by the power receiving coil (primary coil) on the vehicle side. By passing through the secondary coil), a current flows through the power receiving coil, and electric energy is supplied from the power transmitting coil to the power receiving coil. The electromagnetic induction method is a technology that has attracted particular attention because of its high power receiving efficiency.

In such a tire / wheel assembly, it is desirable to suppress the occurrence of the hydroplaning phenomenon when the tire travels straight. It is also desirable to ensure the wear resistance of the tire.

An object of the present invention is to provide a tire / wheel assembly capable of improving hydroplaning performance when a tire travels straight while ensuring wear resistance of the tire.

The gist structure of the present invention is as follows.
(1) The tire / wheel assembly of the present invention is
A tire having a tread part and a wheel having a rim part
The tire is attached to the rim portion and is mounted on the rim portion.
The tire / wheel assembly includes a power receiving coil.
The tread portion has a circumferential main groove extending in the circumferential direction of one or more tires.
The negative ratio of the circumferential main groove of one half of the tread portion in the tire width direction on the inner side when mounted on the vehicle is the negative rate of the other half in the tire width direction of the tread portion on the outer side when mounted on the vehicle. It is characterized in that it is larger than the negative ratio of the circumferential main groove.
Here, the "tread surface" refers to a surface of the ground contact surface that comes into contact with the road surface over the entire tire circumferential direction when the tire / wheel assembly is filled with the specified internal pressure and the maximum load is applied.
The "circumferential main groove" is a groove extending in the circumferential direction of the tire, and the groove width (opening width) when the tire / wheel assembly is filled with the specified internal pressure and no load is applied is 2 mm or more. To say.
The "negative rate of the circumferential main groove" means the ratio of the total groove area of one or more circumferential main grooves to the area of the tread tread.

The "rim" of the above "wheel" is an industrial standard that is effective in the area where tires are produced and used. In Japan, JATMA (Japan Automobile Tire Association) JATMA YEAR BOOK, and in Europe, ETRTO (The European). STANDARDS MANUAL of Tire and Rim Technical Organization), YEAR BOOK of TRA (The Tire and Rim Association, Inc.) in the United States, etc. In the case of "Measuring Rim", "Design Rim in YEAR BOOK of TRA" (that is, the "rim portion" of the above "wheel" includes a size that may be included in the above industrial standard in the future in addition to the current size. As an example of "size described in the future", the size described as "FUTURE DEVELOPMENTS" in the ETRTO 2013 edition can be mentioned.) If the size is not described in the above industrial standard, the tire A rim with a width corresponding to the bead width of.
In addition, the "specified internal pressure" refers to the air pressure (maximum air pressure) corresponding to the maximum load capacity of a single wheel in the applicable size / ply rating described in the above JATMA, etc., and is of a size not described in the above industrial standard. In this case, the "specified internal pressure" shall mean the air pressure (maximum air pressure) corresponding to the maximum load capacity specified for each vehicle on which the tires are mounted.
Further, the "maximum load" means a load corresponding to the above maximum load capacity.

(2) In the above (1), the groove width of the circumferential main groove is preferably 3 mm or more.
The groove width and groove depth of the main groove in the circumferential direction refer to the groove width (opening width) and groove depth (maximum depth) when the tire / wheel assembly is filled with the specified internal pressure and no load is applied. ..
Hereinafter, unless otherwise specified, the dimensions and the like refer to the dimensions and the like when the tire / wheel assembly is filled with the specified internal pressure and no load is applied.

(3) In the above (1) or (2), the thickness of the tread portion is preferably 8 to 25 mm.
Here, the "thickness of the tread portion" refers to the thickness from the outer surface to the inner surface of the tire, including other members such as the belt, carcass ply, and inner liner in addition to the tread rubber, and is the tire equator. In terms of surface, it means the thickness of the tread portion measured in the tire radial direction. However, when the tire equatorial plane has a groove, the thickness of the tread portion measured in the tire radial direction on the tire equatorial plane is defined by a virtual line assuming that there is no groove.

According to the present invention, it is possible to provide a tire / wheel assembly capable of improving the hydroplaning performance when the tire travels straight while ensuring the wear resistance of the tire.

It is the schematic which shows the wireless power receiving system which has the tire wheel assembly which concerns on one Embodiment of this invention by the cross section in the tire width direction. It is a tire width direction sectional view of the tire. It is sectional drawing in the width direction of a wheel. It is the schematic which shows the wireless power receiving system which has the tire wheel assembly of the modified example which concerns on one Embodiment of this invention by the cross section in the tire width direction. It is a developed view which shows the tread pattern of the tire of the tire-wheel assembly which concerns on one Embodiment of this invention. It is a development view which shows another example of a tread pattern. It is a tire width direction partial cross-sectional view which shows the main groove in the circumferential direction and the periphery thereof. It is a top view which shows the grounding shape. It is a figure for demonstrating the action effect in the case of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Hereinafter, unless otherwise specified, the dimensions and the like refer to the dimensions and the like when the tire / wheel assembly is filled with the specified internal pressure and no load is applied.

<Wireless power receiving system>
FIG. 1 is a schematic view schematically showing a wireless power receiving system having a tire / wheel assembly according to an embodiment of the present invention with a cross section in the tire width direction. The wireless power receiving system 1 is a system configured to receive electric power transmitted wirelessly (that is, wirelessly) from an external power transmission device. Explaining the external configuration of the wireless power receiving system first, the power transmission device 40 includes a power transmission coil (primary coil) 41. The power transmission device 40 is installed on a road surface such as a road, or is buried so as to be located near the road surface. The power transmission coil 41 generates an alternating magnetic field based on the alternating current supplied from the power source. The power transmission coil 41 is formed in an annular shape as a whole, and is arranged so that the axial direction of the ring is substantially perpendicular to the road surface so as to generate an alternating magnetic field toward the upper side of the road surface. However, in the drawing, the power transmission coil 41 is modeled. The power transmission coil 41 included in the power transmission device 40 is wound around a core such as a ferrite core to form an annular shape as a whole, but is not limited to this, and an alternating magnetic field such as a coil spring or an air core coil can be applied. It can be any coil that can be generated.
As shown in FIG. 1, the wireless power receiving system 1 includes a tire / wheel assembly 3 according to an embodiment of the present invention. The power receiving device 30 that receives the electric power supplied by radio is housed in the accommodating portion of the tire / wheel assembly 3 (the accommodating portion is a space inside the tire / wheel assembly 3). Hereinafter, the tire / wheel assembly 3 will be described.

≪Tire / Wheel Assembly≫
As shown in FIG. 1, the tire / wheel assembly 3 according to the embodiment of the present invention includes a tire 10 and a wheel 20 having a rim portion 21. The tire 10 is attached to the rim portion 21 of the wheel 20. Hereinafter, the tire 10 and the wheel 20 will be described in order.

(tire)
First, the configuration of an example of the tire 10 will be described. FIG. 2 is a cross-sectional view of the tire 10 in the tire width direction. As shown in FIG. 2, the tire 10 has a pair of bead portions 11, a pair of sidewall portions 12 connected to the bead portions 11, and a tread portion 13 connected to the pair of sidewall portions 12. ing.

In this example, the bead portion 11 has a bead core 11A and a bead filler 11B. The bead core 11A includes a plurality of bead wires around which the bead core 11A is covered with rubber in this example. The bead wire is formed by a steel cord in this example. The bead filler 11B is made of rubber or the like and is located outside the bead core 11A in the tire radial direction. In this example, the bead filler 11B has a substantially triangular cross section in which the thickness decreases toward the outside in the radial direction of the tire. On the other hand, in the present invention, the tire 10 may have a structure that does not have the bead core 11A or the bead filler 11B.

In the present invention, the bead wire can also be formed of a non-magnetic material. This is because the bead wire is made of a non-magnetic material so that the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 is not obstructed by the bead wire. Here, the non-magnetic material refers to a material other than the magnetic material, and the magnetic material refers to a material exhibiting ferromagnetism (ferromagnet). Therefore, the non-magnetic material includes a paramagnetic material and a diamagnetic material having a small magnetic permeability. As the non-magnetic material, for example, a resin material containing a thermoplastic resin such as polyester and nylon, a thermosetting resin such as vinyl ester resin and unsaturated polyester resin, and other synthetic resins can be used. The resin material can further contain fibers such as glass, carbon, graphite, aramid, polyethylene, and ceramic as reinforcing fibers. As the non-magnetic material, not only resin but also any non-metal material including rubber, glass, carbon, graphite, aramid, polyethylene, ceramic and the like can be used. Further, as the non-magnetic material, a metal material containing a paramagnetic material such as aluminum or a diamagnetic material such as copper can be used.

As shown in FIG. 2, the tire 10 has a carcass 14 straddling a pair of bead portions 11 in a toroidal shape. The end side of the carcass 14 is locked to the bead core 11A. Specifically, the carcass 14 has a carcass main body 14A arranged between the bead cores 11A and a carcass folded portion 14B that is folded around the bead core 11A from the inside in the tire width direction to the outside in the tire width direction. ing. The extending length of the carcass folding portion 14B from the inside in the tire width direction to the outside in the tire width direction can be appropriately set. Further, the carcass 14 may have a structure that does not have the carcass folding portion 14B, or may have a structure in which the carcass folding portion 14B is wound around the bead core 11A.

The carcass 14 can be composed of one or more carcass plies. For example, the carcass 14 can be composed of two carcass layers arranged so as to be laminated in the tire radial direction on the equatorial plane CL of the tire. In the present embodiment, the carcass cord constituting the carcass layer of the carcass 14 is made of a non-magnetic material (organic fiber in this example). Alternatively, the carcass cord constituting the carcass 14 may be composed of a steel cord.
Non-magnetic materials include paramagnetic and diamagnetic materials with low magnetic permeability. As the non-magnetic material, for example, a resin material containing a thermoplastic resin such as polyester and nylon, a thermosetting resin such as vinyl ester resin and unsaturated polyester resin, and other synthetic resins can be used. The resin material can further contain fibers such as glass, carbon, graphite, aramid, polyethylene, and ceramic as reinforcing fibers. As the non-magnetic material, not only resin but also any non-metal material including rubber, glass, carbon, graphite, aramid, polyethylene, ceramic and the like can be used. Further, as the non-magnetic material, a metal material containing a paramagnetic material such as aluminum or a diamagnetic material such as copper can be used.
In the present invention, a steel cord can be used as the carcass cord, but it is preferable to use a carcass cord made of a non-magnetic material. This is because the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 can be prevented from being obstructed by the carcass 14, and thus the power receiving efficiency can be improved. In the present embodiment, the carcass 14 has a radial structure, but the present invention is not limited to this, and a bias structure may also be used.

A belt 15 and tread rubber are provided on the outer side of the crown portion of the carcass 14 in the tire radial direction. The belt 15 can be composed of, for example, a plurality of belt layers laminated in the tire radial direction. In the present embodiment, the belt cord forming the belt layer of the belt 15 is made of a non-magnetic material (organic fiber in this example). Alternatively, a steel cord can be used as the belt cord constituting the belt 15.
Non-magnetic materials include paramagnetic and diamagnetic materials with low magnetic permeability. As the non-magnetic material, for example, a resin material containing a thermoplastic resin such as polyester and nylon, a thermosetting resin such as vinyl ester resin and unsaturated polyester resin, and other synthetic resins can be used. The resin material can further contain fibers such as glass, carbon, graphite, aramid, polyethylene, and ceramic as reinforcing fibers. As the non-magnetic material, not only resin but also any non-metal material including rubber, glass, carbon, graphite, aramid, polyethylene, ceramic and the like can be used. Further, as the non-magnetic material, a metal material containing a paramagnetic material such as aluminum or a diamagnetic material such as copper can be used.
In the present invention, a steel cord can be used as the belt cord constituting the belt 15, but it is preferable to use a belt cord made of a non-magnetic material. This is because the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 can be prevented from being obstructed by the belt 15, and thus the power receiving efficiency can be improved. In the present invention, the number of layers of the belt layer, the inclination angle of the belt cord, the width of each belt layer in the tire width direction, and the like are not particularly limited and can be appropriately set.

As shown in FIG. 2, the tire 10 has an inner liner 16. The inner liner 16 is arranged so as to cover the inner surface of the tire 10. The inner liner 16 can be composed of one or more inner liner layers laminated in the tire radial direction on the equatorial surface CL of the tire. The inner liner 16 is made of, for example, a butyl rubber having low air permeability. Butyl rubber includes, for example, butyl rubber and a halogenated butyl rubber which is a derivative thereof. The inner liner 16 is not limited to the butyl rubber, and may be composed of other rubber compositions, resins, or elastomers.

In the present invention, the sidewall portion 12 may have a side reinforcing rubber (not shown). The side reinforcing rubber may have a crescent-shaped cross section, for example. As a result, when the tire is punctured, the side reinforcing rubber can take over the load and run. Further, in the present invention, the rubber or the side reinforcing rubber constituting the sidewall portion 12 may contain a magnetic material having a high magnetic permeability (for example, a ferromagnetic material) such as ferrite. As a result, the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 can be made less likely to be attenuated by the influence of the metal and other magnetic fields existing outside the sidewall portion 12 in the tire width direction, and thus the power receiving efficiency can be improved. Can be improved.

The tire is preferably a passenger car tire, and more preferably a passenger car radial tire.

In each of the above examples, when the cross-sectional width SW of the tire 10 is less than 165 (mm), the ratio SW / OD of the cross-sectional width SW of the tire 10 to the outer diameter OD is 0.26 or less. If the cross-sectional width SW of the tire 10 is 165 (mm) or more, the cross-sectional width SW (mm) and the outer diameter OD (mm) of the tire 10 are determined.
OD (mm) ≥ 2.135 x SW (mm) + 282.3 (mm)
(Hereinafter referred to as "relational expression (1)")
It is preferable to satisfy.
By satisfying the above ratio SW / OD or the relational expression (1), the cross-sectional width SW of the tire 10 becomes relatively small with respect to the outer diameter OD of the tire 10, the air resistance is reduced, and the cross-sectional width is narrow. Therefore, it is possible to secure a vehicle space, and in particular, it is possible to secure an installation space for drive parts near the inside of the tire mounted on the vehicle.
Further, by satisfying the ratio SW / OD or the relational expression (1), the outer diameter OD of the tire 10 becomes relatively large with respect to the cross-sectional width SW of the tire 10, the rolling resistance is reduced, and the tire 10 is further satisfied. As the diameter of the tire increases, the wheel shaft becomes taller and the space under the floor is expanded, so that it is possible to secure a space for a vehicle trunk and the like and a space for installing drive parts.
As described above, by satisfying the above ratio SW / OD or the relational expression (1), it is possible to achieve low fuel consumption with respect to the supplied electric energy, and it is also possible to secure a large vehicle space. ..
Further, the tire 10 has a cross-sectional width SW (mm) and an outer diameter OD (mm) of the tire 10.
OD (mm) ≥ -0.0187 x SW (mm) ² + 9.15 x SW (mm) -380 (mm)
(Hereinafter referred to as "relational expression (2)")
It is preferable to satisfy.
By satisfying the above relational expression (2), the cross-sectional width SW of the tire becomes relatively small with respect to the outer diameter OD of the tire 10, the air resistance is reduced, and the vehicle space is secured due to the narrow cross-sectional width. In particular, it is possible to secure an installation space for drive parts in the vicinity of the inside of the tire 10 mounted on the vehicle.
Further, by satisfying the above relational expression (2), the outer diameter OD of the tire becomes relatively large with respect to the cross-sectional width SW of the tire 10, the rolling resistance is reduced, and the wheel is increased by increasing the diameter of the tire 10. Since the shaft is raised and the space under the floor is expanded, it is possible to secure a space such as a trunk of a vehicle and a space for installing drive parts.
As described above, by satisfying the above relational expression (2), it is possible to achieve low fuel consumption with respect to the supplied electric energy, and it is also possible to secure a large vehicle space.
In each of the above examples, the tire 10 preferably satisfies the ratio SW / OD and / or the relational expression (2), or preferably satisfies the relational expression (1) and / or the relational expression (2). ..

In each of the above examples, it is preferable that the tire width direction cross-sectional area S1 of the bead filler 11B is 1 time or more and 8 times or less the tire width direction cross-sectional area S2 of the bead core 11A. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
In the case of a sandwiched bead core structure in which the carcass is held from the inside and the outside in the tire width direction, the total volume of the bead cores inside and outside in the width direction of the carcass is defined as S2.
By setting the cross-sectional area S1 of the bead filler 11B to the above range, the volume of the bead filler, which is a high-rigidity member, can be reduced, the vertical spring constant of the tire can be reduced, and the riding comfort can be improved. It is also possible to reduce the weight of the bead filler and reduce the weight of the tire, and therefore the rolling resistance value of the tire is further reduced.
In particular, in a narrow-width / large-diameter tire that satisfies the above relational expression (1) or (2), the tension rigidity of the belt is high and the tension rigidity of the tire side portion is lower than that of the belt. In addition, the effect of reducing the vertical spring constant by setting the cross-sectional area S1 of the bead filler within a predetermined range becomes very high.
Here, by setting the cross-sectional area S1 of the bead filler 11B in the tire width direction to 8 times or less the cross-sectional area S2 of the bead core 11A in the tire width direction, the volume of the bead filler, which is a high-rigidity member, is prevented from becoming too large. By preventing the vertical spring constant from becoming too large, it is possible to suppress a decrease in ride comfort.
On the other hand, by setting the tire width direction cross-sectional area S1 of the bead filler 11B to one or more times the tire width direction cross-sectional area S2 of the bead core 11A, the rigidity of the bead portion is ensured and the lateral spring coefficient does not decrease too much. In this way, steering stability can be ensured.

In each of the above examples, when the width of the bead filler 11B in the tire width direction at the center position in the tire radial direction is BFW and the maximum width of the bead core 11A in the tire width direction is BDW,
0.1 ≤ BFW / BDW ≤ 0.6
It is preferable to satisfy.
As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting the ratio BFW / BDW to 0.6 or less, the volume of the bead filler is reduced while maintaining the height of the bead filler, the rigidity in the tire rotation direction is secured, and the vertical spring constant is reduced for riding. The comfort can be improved and the weight of the tire can be reduced.
On the other hand, by setting the ratio BFW / BDW to 0.1 or more, the rigidity of the bead portion can be ensured, the lateral spring constant can be maintained, and the steering stability can be further ensured.

In each of the above examples, when the height of the bead filler 11B in the tire radial direction is BFH and the section height (tire cross-sectional height) of the tire is SH.
0.1 ≤ BFH / SH ≤ 0.5
It is preferable to satisfy.
As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting the ratio BFH / SH to 0.5 or less, the radial height of the bead filler, which is a high-rigidity member, is reduced, the vertical spring constant of the tire is effectively reduced, and the riding comfort is improved. Can be done.
On the other hand, by setting the ratio BFH / SH to 0.1 or more, the rigidity of the bead portion can be ensured, the lateral spring constant can be maintained, and the steering stability can be further ensured.
Here, the tire section height SH is 1 / of the difference between the outer diameter of the tire and the rim diameter in the no-load state when the tire is incorporated in the rim and the internal pressure specified for each vehicle to which the tire is mounted is applied. It shall refer to 2.

The height BFH of the bead filler 11B in the tire radial direction is preferably 45 mm or less. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.

In each of the above examples, the tire 10 has a gauge Ts of the sidewall portion 12 in the tire maximum width portion (measured in this cross section in the normal direction of the tangent line at a point on the tire surface in the tire maximum width portion) and a bead core. It is preferable that the ratio Ts / Tb with the bead width Tb (the width of the bead portion 11 in the tire width direction) at the center position in the tire radial direction of 11A is 15% or more and 60% or less. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
The "maximum tire width portion" refers to the maximum width position in the cross section in the tire width direction when the tire is mounted on the rim and is in a no-load state.
Gauge Ts is the total thickness of all members such as rubber, reinforcing members, and inner liner.
By setting the ratio Ts / Tb to the above range, it is possible to appropriately reduce the rigidity in the maximum width portion of the tire having a large bending deformation under a tire load, reduce the vertical spring constant, and improve the riding comfort. ..
That is, if the ratio Ts / Tb exceeds 60%, the gauge of the sidewall portion 12 in the maximum tire width portion becomes large, the rigidity of the sidewall portion 12 becomes high, and the vertical spring coefficient may become high. is there. On the other hand, if the ratio Ts / Tb is less than 15%, the lateral spring constant may be too low to ensure steering stability.

In each of the above examples, the tire 10 preferably has a gauge Ts of the sidewall portion 12 at the maximum width portion of the tire of 1.5 mm or more. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting the gauge Ts to 1.5 mm or more, it is possible to maintain an appropriate rigidity in the maximum tire width portion, suppress a decrease in the lateral spring coefficient, and further secure steering stability.

In each of the above examples, the tire 10 preferably has a bead core 11A having a diameter Tbc (maximum width of the bead core in the tire width direction) of 3 mm or more and 16 mm or less. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting the Tbc to 3 mm or more, it is possible to realize weight reduction while ensuring the flexural rigidity and torsional rigidity on the rim flange, while by setting the Tbc to 16 mm or less, the weight increase can be suppressed. , Steering stability can be ensured.
Further, in the case of a structure in which the bead core is divided into a plurality of small bead cores by a carcass, the distance between the innermost end portion and the outermost outermost end portion in the width direction of all the small bead cores may be Tbc.

^{In each of the above examples, the tire 10 preferably has a ground contact area of 8000 mm 2} or more when a maximum load specified for each vehicle to which the tire is mounted is applied. As a result, it is possible to achieve both a reduction in the rolling resistance value of the tire and a reduction in the weight of the tire, and it is possible to preferably achieve both the power supply efficiency and the low fuel consumption. In addition, the tire axial force can be secured to improve the stability and safety of the vehicle.

In each of the above examples, the tire 10 preferably has a belt cord Young's modulus of 40,000 MPa or more. As a result, the carcass structure and belt rigidity can be optimized, and the strength of the tire that can be used even at a high internal pressure can be secured. In addition, power supply efficiency and fuel efficiency can be suitably compatible with each other.

In each of the above examples, the tire 10 preferably has an inner liner 16 having a thickness of 0.6 mm or more. This makes it possible to suppress air leakage in a high internal pressure state. In addition, power supply efficiency and fuel efficiency can be suitably compatible with each other.

In each of the above examples, it is preferable that the ratio Ts / Tc of the gauge Ts of the sidewall portion 12 in the maximum width portion of the tire to the diameter Tc of the carcass cord is 4 or more and 12 or less. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting the ratio Ts / Tc to the above range, it is possible to appropriately reduce the rigidity in the maximum width portion of the tire having a large bending deformation under a tire load, reduce the vertical spring constant, and improve the riding comfort. ..
That is, by setting the ratio Ts / Tc to 12 or less, the gauge of the sidewall portion 4 in the maximum tire width portion is prevented from becoming too large, the rigidity of this portion is increased, and the longitudinal spring coefficient is increased. Can be suppressed. On the other hand, by setting the ratio Ts / Tc to 4 or more, the lateral spring constant does not decrease too much, and steering stability can be ensured.

In each of the above examples, the tire 10 has a ratio Ta / Tc of the distance Ta and the diameter Tc of the carcass cord, where Ta is the distance in the tire width direction from the surface of the carcass cord to the outer surface of the tire in the maximum width portion of the tire. Is preferably 2 or more and 8 or less. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting the ratio Ta / Tc to 8 or less, the gauge of the sidewall portion 12 in the maximum tire width portion is reduced, the rigidity of the sidewall portion 12 is reduced, the vertical spring coefficient is reduced, and the riding comfort is reduced. Can be further improved. On the other hand, by setting the ratio Ta / Tc to 2 or more, the lateral spring constant can be secured and the steering stability can be further ensured.
In addition, "Ta" means the distance in the tire width direction from the surface of the outermost carcass cord in the width direction to the outer surface of the tire in the tire maximum width portion.
That is, when the carcass folded portion 14B extends radially outward from the maximum tire width portion, the distance in the tire width direction from the surface of the carcass cord 14c of the portion forming the carcass folded portion 14B to the outer surface of the tire is set to Ta. ..

In each of the above examples, the tire 10 preferably has a carcass cord 14c having a diameter Tc of 0.2 mm or more and 1.2 mm or less. As a result, both power supply efficiency and fuel efficiency can be suitably achieved.
By setting Tc to 0.8 mm or less, the vertical spring coefficient can be reduced and riding comfort can be improved. On the other hand, by setting Tc to 0.4 mm or more, the lateral spring coefficient can be increased for maneuvering. Stability can be ensured.

FIG. 5 is a developed view showing a tread pattern of a tire of a tire / wheel assembly according to an embodiment of the present invention.
As shown in FIG. 5, the tire 10 has one or more (one in the illustrated example) circumferential main grooves 17 extending in the circumferential direction of the tire on the tread 13a of the tread portion 13. Here, the negative ratio of the circumferential main groove 17 of one half of the tread portion 13 in the tire width direction of the tread portion 13 on the inside when the vehicle is mounted is the tire width direction of the tread portion 13 on the outside when the vehicle is mounted. It is larger than the negative ratio of the circumferential main groove 17 in the other half.
In the example shown in FIG. 5, the circumferential main groove 17 is located on the tire equatorial plane CL, and the center of the groove width is offset from the tire equatorial plane to one half of the tire width direction (outside when mounted on the vehicle). Have been placed.
Hereinafter, the action and effect of the tire / wheel assembly of the present embodiment will be described.

In the tire 10 of the tire / wheel assembly of the present embodiment, the negative ratio of the circumferential main groove 17 of one half of the tread portion 13a in the tire width direction, which is the inner side when the tread portion 13 is mounted on the vehicle, is the outer side when the tread portion 13 is mounted on the vehicle. It is larger than the negative ratio of the main groove 17 in the circumferential direction of the other half of the tread portion 13 in the tire width direction of the tread portion 13. As a result, it is possible to secure an inner groove area when the tire is mounted on a vehicle and improve the hydroplaning performance when the tire travels straight, which usually results in a long ground contact length (especially when used as a front wheel). Further, it is possible to suppress a decrease in the wear resistance of the tire as compared with the case where the negative rate of both the outside when mounted on the vehicle and the inside when mounted on the vehicle is increased.
As described above, according to the tire / wheel assembly of the present embodiment, it is possible to improve the hydroplaning performance when the tire travels straight while ensuring the wear resistance of the tire.
It should be noted that the deterioration of the drainage property of the tire can be suppressed as compared with the case where the negative rate of both the outside when mounted on the vehicle and the inside when mounted on the vehicle is reduced.

FIG. 6 is a developed view showing another example of the tread pattern.
In the example shown in FIG. 6, the tread 13a of the tread portion 13 has two main grooves 17 in the circumferential direction (one in each half in the tire width direction). Here, the groove width of the circumferential main groove 17 in one half in the tire width direction (inside when mounted on the vehicle) is larger than the groove width of the circumferential main groove 17 in the other half in the tire width direction (outside when mounted on the vehicle). large. As a result, even in the example shown in FIG. 6, the negative rate of the circumferential main groove 17 of one half of the tread portion 13a of the tread portion 13 on the inside when mounted on the vehicle in the tire width direction is the tread portion 13 which is on the outside when mounted on the vehicle. It is larger than the negative ratio of the main groove 17 in the circumferential direction of the other half of the tread 13a in the tire width direction. Therefore, it is possible to secure the groove area on the inside when the tire is mounted on the vehicle, which normally has a long contact length, and improve the hydroplaning performance when the tire goes straight. Compared with the case where the rate is increased, it is possible to suppress a decrease in the wear resistance of the tire.

Here, the negative ratio of the negative rate of one half in the tire width direction (inside when mounted on the vehicle) to the negative rate of the other half in the tire width direction (outside when mounted on the vehicle) may be 20 to 99%. preferable. By setting the negative ratio to 20% or more, it is possible to further secure the inner groove area when the tire is mounted and further improve the hydroplaning performance when the tire goes straight, while the negative ratio is 99. This is because the wear resistance of the tire can be ensured by setting it to% or less. For the same reason, the negative ratio is more preferably 30 to 90%.
Although not particularly limited, the negative rate of the other half in the tire width direction (outside when mounted on the vehicle) can be, for example, 2 to 40%. Further, although not particularly limited, the negative rate of one half in the width direction (inside when mounted on the vehicle) can be, for example, 8 to 41%.

Here, as in the example shown in FIG. 5, it is preferable that the tread portion has a circumferential main groove extending in the tire circumferential direction on the equator surface of the tire.
As described above, the magnetic flux from the power transmission coil 41 is emitted upward from the road surface (for example, substantially perpendicular to the road surface). In the example of FIG. 5, since the tire 10 has a circumferential main groove 17 extending in the tire circumferential direction on the tire equatorial plane CL on the tread 13a of the tread portion 13, most of the magnetic flux generated from the transmission coil 41 is generated. Passes through the circumferential main groove 17 on the tire equatorial plane CL and passes through the power receiving coil 31. Since these magnetic fluxes pass through the portion (air) of the circumferential main groove 17, the magnetic flux trying to reach the power receiving coil 31 is less likely to be hindered than when passing through the portion without the groove (tread rubber). Therefore, more magnetic flux can reach the power receiving coil 31.
Therefore, according to this configuration, high power receiving efficiency can be achieved in the automatic power supply using the electromagnetic induction method.
In some cases, the power transmission coil 41 is arranged diagonally, and the power reception coil 31 is arranged so as to face the power transmission coil 41. That is, the axial direction of the ring of the power transmission coil 41 and the axial direction of the ring of the power receiving coil 31 are arranged so as to be substantially parallel to each other. Even in such a case, as in the above case, more magnetic flux can reach the power receiving coil 31, and high power receiving efficiency can be achieved in automatic power feeding using the electromagnetic induction method.
Even if the axis of the ring of the power transmission coil 41 and the axis of the ring of the power receiving coil 31 are not substantially parallel, the above-mentioned effect can be obtained for a certain degree of magnetic flux, so that high power receiving efficiency can be achieved. Is.

As shown in FIG. 6, it is also preferable that the tread portion has a circumferential main groove extending in the tire circumferential direction without being located on the tire equatorial plane.
As described above, the magnetic flux from the power transmission coil 41 is emitted upward (for example, diagonally) from the road surface. The case where the power transmission coil 41 is located on the side where the circumferential main groove 17 is located will be described.
In this example, the tire 10 is not located on the tire equatorial plane CL but has a circumferential main groove 17 extending in the tire circumferential direction on the tread 13a of the tread portion 13, so that the tire 10 is generated obliquely from the transmission coil 41. Most of the magnetic flux generated passes through the main groove 17 in the circumferential direction and passes through the power receiving coil 31. Since these magnetic fluxes pass through the portion (air) of the circumferential main groove 17, the magnetic flux trying to reach the power receiving coil 31 is less likely to be hindered than when passing through the portion without the groove (tread rubber). Therefore, more magnetic flux can reach the power receiving coil 31.
Therefore, according to this configuration, high power receiving efficiency can be achieved in the automatic power supply using the electromagnetic induction method.
In this example, the power receiving coil 31 is also arranged diagonally, and the power receiving coil 31 is arranged so as to face the power transmission coil 41. That is, the axial direction of the ring of the power transmission coil 41 and the axial direction of the ring of the power receiving coil 31 are arranged so as to be substantially parallel to each other. Even in such a case, as in the above case, more magnetic flux can reach the power receiving coil 31, and high power receiving efficiency can be achieved in automatic power feeding using the electromagnetic induction method.
Even when the ring of the power transmission coil 41 is arranged substantially parallel to the road surface, the above-mentioned effect can be obtained if the circumferential main groove 17 is located above the power transmission coil 41.

As shown in the illustrated example, it is most preferable that the circumferential main groove 17 extends straight in the tire circumferential direction. On the other hand, the circumferential main groove 17 may extend in the tire circumferential direction while being zigzag or curved. In this case, in order to improve the power feeding efficiency, the circumferential main groove 17 has a groove portion extending straight and continuously in the tire circumferential direction (see-through portion (groove when the kicking side is viewed from the stepping side at the time of touchdown). It is preferable to have a part) where the kicking side can be seen without being blocked by the wall).
The groove width (opening width) of the circumferential main groove 17 is preferably 2% or more of the tread width TW. This is because the power receiving efficiency can be further improved. For the same reason, the groove width of the circumferential main groove 17 is more preferably 4% or more of the tread width TW. On the other hand, from the viewpoint of ensuring the rigidity of the land portion and improving the wear resistance, the groove width of the circumferential main groove 17 is preferably 20% or less of the tread width TW. For the same reason, the groove width of the circumferential main groove 17 is more preferably 15% or less of the tread width TW. Here, the "tread width" refers to the distance in the tire width direction between the ground contact ends (both ends in the tire width direction of the ground contact surface) when the tire / wheel assembly is filled with the specified internal pressure and no load is applied. And.
Although not particularly limited, the groove width (opening width) of the circumferential main groove 17 is preferably 3 mm or more. This is because the power receiving efficiency can be further improved. For the same reason, the groove width of the circumferential main groove 17 is more preferably 5 mm or more, although it is not particularly limited. On the other hand, from the viewpoint of ensuring the rigidity of the land portion and improving the wear resistance, the groove width of the circumferential main groove 17 is preferably 30 mm or less, although it is not particularly limited. For the same reason, the groove width of the circumferential main groove 17 is more preferably 20 mm or less.
The groove width and groove depth refer to the groove width and groove depth when the tire / wheel assembly is filled with the specified internal pressure and no load is applied.
The groove depth of the circumferential main groove 17 is preferably 15% or more of the thickness of the tread portion. This is because the power receiving efficiency can be further improved. For the same reason, the groove depth of the circumferential main groove 17 is more preferably 20% or more of the thickness of the tread portion. On the other hand, from the viewpoint of ensuring the rigidity of the land portion and improving the wear resistance, the groove depth of the circumferential main groove 17 is preferably 70% or less of the thickness of the tread portion. For the same reason, the groove depth of the circumferential main groove 17 is more preferably 50% or less of the thickness of the tread portion.
Although not particularly limited, the groove depth (maximum depth) of the groove in the width direction is preferably 2 mm or more. This is because the power receiving efficiency can be further improved. For the same reason, the groove depth of the groove in the width direction is preferably 3 mm or more, although it is not particularly limited. On the other hand, from the viewpoint of ensuring the rigidity of the land portion and improving the wear resistance, the groove depth of the groove in the width direction is preferably 10 mm or less, although it is not particularly limited. For the same reason, the groove depth of the circumferential main groove 17 is preferably 8 mm or less, although it is not particularly limited.
The groove in the width direction may extend in the tire width direction, or may extend at an angle with respect to the tire width direction. The width direction groove may extend straight, may have one or more bent points, and the inclination angle may gradually decrease or gradually increase from the outside to the inside in the tire width direction. When the width direction groove is inclined, the inclination angle of the width direction groove (when the inclination angle changes in the tire width direction, the inclination angle formed by the line segment connecting both ends of the width direction groove) is not particularly limited. It can be 0 ° to 45 ° with respect to the tire width direction.
The pitch length of the groove in the width direction in the tire circumferential direction is not particularly limited, but can be 10 to 50 mm. In the tread of the tire, the groove that is connected without being divided in the middle from one side in the tire circumferential direction to the other side is a circumferential groove (including the circumferential main groove), and the other grooves are in the width direction. Make a groove.
The thickness of the tread portion is not particularly limited, but is preferably 25 mm or less. This is because it is possible to improve the power receiving efficiency while improving the fuel efficiency. For the same reason, the thickness of the tread portion is more preferably 20 mm or less. On the other hand, although not particularly limited, the thickness of the tread portion is preferably 8 mm or more from the viewpoint of ensuring wear resistance. For the same reason, the thickness of the tread portion is more preferably 10 mm or more.
In each of the above examples, the tread 13a of the tread portion 13 does not have a circumferential sipe extending in the tire circumferential direction or a width sipe extending in the tire width direction, but one or more circumferential sipe and / or It is also possible to provide one or more width direction sipes. The circumferential sipe refers to a tire / wheel assembly having a groove width (opening width) of less than 2 mm when the tire / wheel assembly is filled with a specified internal pressure and no load is applied. The width direction sipe refers to a tire / wheel assembly having a groove width (opening width) of less than 2 mm when the specified internal pressure is applied and no load is applied.
The negative rate of the entire tread 13a of the tread portion 13 is not particularly limited, but can be 8 to 40%. Drainage can be further improved by setting the negative rate of the entire tread 13a of the tread portion 13 to 8% or more, while wear resistance can be improved by setting the negative rate of the entire tread 13a of the tread portion 13 to 40% or less. You can improve your sex. For the same reason, the negative rate of the entire tread 13a of the tread portion 13 is more preferably 15 to 35%.

Regarding the arrangement of the circumferential main grooves, it is also preferable that the tread portion has no circumferential main groove extending in the tire circumferential direction in the region where the surface of the power receiving coil is projected in the direction orthogonal to the surface. This is because it is possible to prevent the groove from accumulating in the main groove in the circumferential direction and reducing the power receiving efficiency.

In the example shown in FIG. 7, the tire 10 has a shoulder land portion 19 divided by a tread end (the above-mentioned ground contact end) and a circumferential main groove 17 extending in the tire circumferential direction on the tread 13a of the tread portion 13. doing. The inclination angle θ1 formed by the wall surface of the shoulder land portion 19 partitioned by the circumferential main groove 17 is larger than the inclination angle θ2 formed by the wall surface of the land portion partitioned inside the tire width direction by the circumferential main groove 17.
According to this configuration, the shape of the shoulder land portion becomes a shape in which the width in the tire width direction expands from the outside to the inside in the tire radial direction in a cross-sectional view, so that the rigidity of the shoulder land portion is increased. The wear resistance of the shoulder portion can be improved. Therefore, wear of the shoulder portion of the tire can be suppressed.
The inclination angle θ1 can be made larger than the inclination angle θ2 on both sides in the tire width direction of the tire, and the inclination angle θ1 can be made larger than the inclination angle θ2 only in one half of the tire 10 in the tire width direction. You can also. In this case, wear of the shoulder portion can be suppressed at the one half portion.
Here, the difference in inclination angles θ1-θ2 is preferably more than 0 ° and 50 ° or less. By making the difference θ1-θ2 larger than 0 °, the wear resistance of the shoulder part can be further improved by improving the rigidity due to the shape of the shoulder land part, while the difference θ1-θ2 is set to 50 ° or less. This is because the volume of the main groove in the circumferential direction is not increased, the rigidity of the shoulder land portion is ensured, and the wear resistance of the shoulder portion can be further improved. For the same reason, the difference θ1-θ2 is more preferably 1 to 30 °. For the same reason, the difference θ1-θ2 is more preferably 2 to 15 °.

As an example, it is preferable that the negative ratio of the widthwise groove of the tread portion of the tread portion is smaller than the negative ratio of the circumferential main groove of the tread portion of the tread portion.
The "negative rate of the width direction groove" means the ratio of the total groove area of one or more width direction grooves to the area of the tread tread, and when there is no width direction groove, the negative rate of the width direction groove is used. It is set to 0%.
The tire may have one or more (for example, one) circumferential main grooves extending in the circumferential direction of the tire on the tread surface of the tread portion. For example, a tire can have one or more widthwise grooves extending in the tire width direction. The width direction groove may extend inward in the tire width direction from the tread end. Alternatively, the configuration may not have a groove in the width direction.
According to this, it is possible to reduce the hitting sound when the tire rolls due to the groove in the width direction and improve the quietness of the tire. In addition, it is possible to suppress a decrease in drainage property as compared with a case where the negative ratios of both the circumferential main groove and the width direction groove are reduced. Further, the decrease in wear resistance can be suppressed as compared with the case where the negative ratios of both the circumferential main groove and the width direction groove are increased.
The ratio of the negative rate of the width direction groove to the negative rate of the circumferential main groove is preferably 0 to 70%. When there is no groove in the width direction (when the negative rate is 0%), there is no hitting sound when the tire rolls, and the quietness is particularly improved. By setting the above ratio to more than 0%, the decrease in drainage property can be further suppressed, while by setting the above ratio to 70% or less, the quietness of the tire can be further improved. Is. For the same reason, the ratio is more preferably 10 to 60%.
Here, in order to reduce the negative ratio of the width direction groove as described above, the groove width of the width direction groove can be made small (for example, 15 mm or less, although not particularly limited), or for example, the tire circumferential direction. The pitch length of the tire can be increased (for example, 10 mm or more, but is not particularly limited). An asymmetric pattern can also be used. For example, in one tire width direction half portion with the tire equatorial plane CL as a boundary, the groove width of the width direction groove is made small (for example, 14 mm or less, but is not particularly limited), and the other In the half portion of the tire in the width direction of the tire, the pitch length of the groove in the width direction in the tire circumferential direction can be increased (for example, 11 mm or more, although not particularly limited).

As another example, it is also preferable that the negative ratio of the widthwise groove of the tread portion of the tread portion is greater than or equal to the negative ratio of the circumferential main groove of the tread portion of the tread portion.
The tire may have one or more (for example, one) circumferential main grooves extending in the circumferential direction of the tire on the tread surface of the tread portion. For example, a tire can have one or more widthwise grooves extending in the tire width direction, for example, the widthwise grooves can extend inward in the tire width direction from the tread end.
According to this, the drainage property due to the groove in the width direction can be largely secured, and the hydroplaning performance (particularly, the hydroplaning performance at the time of cornering) can be improved. Further, the wear resistance of the tire can be ensured as compared with the case where the negative ratios of both the circumferential main groove and the width direction groove are increased. Further, the drainage property of the tire can be improved as compared with the case where the negative ratios of both the circumferential main groove and the width direction groove are reduced.
The ratio of the negative rate of the width direction groove to the negative rate of the circumferential main groove is preferably 100 to 200%. By setting the above ratio to 100% or more, the hydroplaning performance at the time of cornering of the tire can be further improved, while by setting the above ratio to 200% or less, the wear resistance of the tire is further improved. Because it can be done. For the same reason, the ratio is more preferably 110 to 180%.
Here, in order to make the negative ratio of the width direction groove relatively large, for example, the extending length can be secured by forming the width direction groove into a curved shape, or for example, the groove of the width direction groove. The width may be large (for example, 1 mm or more, but is not particularly limited). Alternatively, the pitch length in the tire circumferential direction can be reduced (for example, 50 mm or less, but not particularly limited). An asymmetric pattern can also be used. For example, one main groove in the circumferential direction is arranged in one half portion in the tire width direction with the tire equatorial plane CL as a boundary, and one circumferential main groove is arranged in the other half portion in the tire width direction. It does not have a directional main groove, and in one half of the above, the pitch length of the groove in the width direction is made smaller (than the other half), and in the other half of the above, the groove in the width direction is curved. By doing so, the extended length can be secured.

FIG. 8 is a plan view showing the ground contact shape. FIG. 9 is a diagram for explaining the action and effect in the case of FIG. As shown in FIG. 8, on the ground contact surface when the tire / wheel assembly is filled with the specified internal pressure and the maximum load is applied, from the end in the tire width direction with respect to the ground contact length LC at the center of the ground contact surface in the tire width direction. The rectangular ratio, which is the ratio of the contact patch length LE at the position in the tire width direction separated by 10% of the contact patch width W inside the tread width direction, is preferably 50% or more.
Here, the "ground contact width" refers to the distance in the tire width direction between the ground contact ends when the tire / wheel assembly is filled with the specified internal pressure and the maximum load is applied.
As schematically shown in FIG. 9, when the rectangular ratio is small (indicated by a broken line), a space is created between the tire and the road surface, and water, foreign matter, etc. enter between them to hinder the magnetic flux and receive power efficiency. However, by setting the rectangular ratio within the above range (shown by the solid line), the space between the tire and the road surface is eliminated so that the magnetic flux is not obstructed by water, foreign matter, etc. , The power receiving efficiency can be improved.
Therefore, high power receiving efficiency can be achieved in automatic power supply using the electromagnetic induction method. Further, when the rectangular ratio is 50% or more, the energy loss is small, so that the fuel efficiency is also improved.
From the viewpoint of further improving the power receiving efficiency and further improving the fuel efficiency, the rectangular ratio is more preferably 60% or more, further preferably 70% or more, and most preferably 80% or more. preferable. On the other hand, from the viewpoint of improving wear resistance, the rectangular ratio is preferably 110% or less.
In order to make the rectangular ratio 50% or more (preferably 60% or more, 70% or more, 80% or more), it is preferable to appropriately reduce the circumferential rigidity of the shoulder portion. For example, in the tire width direction region including the position in the tire width direction separated by 10% of the ground contact width W from the end in the tire width direction to the inside in the tread width direction, the belt reinforcing layer is not arranged, or the number of layers of the belt reinforcing layer is set to another. The number of layers of the belt layer, which is smaller than that of the region, can be reduced as compared with other regions.

Further, when the tire / wheel assembly is provided with an in-wheel motor and a power receiving device, the tread portion has a land portion located on the equatorial plane of the tire, and the tire / wheel assembly is filled with the specified internal pressure. In the state of no load, the width of the land portion in the tire width direction is preferably 15% or more of the tread width. Even when a large torque is momentarily applied to the tread portion of the tire by driving the in-wheel motor, the width of the land portion on the equatorial plane of the tire to which the maximum torque is applied in the tire width direction is 15% or more of the tread width. This is because the rigidity is high, so that the deformation of the land portion can be suppressed and the wear resistance of the tire can be improved. For the same reason, the width of the land portion in the tire width direction is more preferably 20% or more of the tread width. For the same reason, the width of the land portion in the tire width direction is more preferably 30% or more of the tread width. From the viewpoint of appropriately reducing the rigidity of the land portion on the equator surface of the tire and improving the wear resistance, the width of the land portion on the equator surface of the tire in the tire width direction is 70% of the tread width. The following is preferable.

Further, as an example, in a state where the tire / wheel assembly is filled with the specified internal pressure and no load is applied, the tread is separated from the tread end TE inward in the tire width direction by 1/8 of the tread width TW in a cross-sectional view in the tire width direction. When the point on the surface is 1/8 point (point P), in the above state, the thickness T2 of the tread portion 13 at the 1/8 point (point P) is the tread on the tire equatorial plane CL. It is preferable that the thickness of the portion 13 is smaller than T1.
According to this, it becomes difficult for the tread rubber to prevent the magnetic flux passing through the above 1/8 point from reaching the power receiving coil 31 (for example, when the ring of the power transmission coil 41 is arranged diagonally with respect to the road surface). , The power receiving efficiency can be improved. Further, the wear resistance of the tire can be ensured as compared with the case where the tread thickness is reduced over the entire width direction of the tire. The above-mentioned effects can be obtained if the power transmission coil 41 and the power reception coil 31 are arranged so that at least a part of the magnetic flux can pass through the above 1/8 point.
Further, the tire 10 is a half portion on both sides in the tire width direction with the tire equatorial plane CL as a boundary, and in the above state, the thickness T2 of the tread portion 13 at the above 1/8 point (point P) is the tire. The thickness of the tread portion 13 on the equatorial plane CL can be made smaller than the thickness T1, or the tread portion 13 at the above 1/8 point (point P) in the above state in only one half of the tread portion 13. The thickness T2 can be made smaller than the thickness T1 of the tread portion 13 on the tire equatorial plane CL.
Here, the ratio T2 / T1 of the thickness T2 of the tread portion at the above 1/8 point to the thickness T1 of the tread portion on the equatorial plane of the tire is preferably 60 to 99%. By setting the ratio T2 / T1 to 60% or more, the wear resistance of the tire can be improved, while by setting the ratio T2 / T1 to 99% or less, the power receiving efficiency is further improved. Because it can be done. For the same reason, the ratio T2 / T1 is more preferably 65 to 95%.
Further, it is also preferable that the thickness of the tread portion gradually decreases from the tire equatorial plane CL toward the above 1/8 point (point P). This is because the power receiving efficiency can be improved while preventing the occurrence of a rigidity step in the tire width direction.
It is also possible to make the thickness T2 smaller than the thickness T1 by providing a step portion in the thickness of the tread between the tire equatorial plane CL and the above 1/8 point (point P). In this case, it is preferable to provide a step with the main groove in the circumferential direction as a boundary (that is, to have no step in one land portion).
Here, in the above case, the thickness T1 of the tread portion on the equatorial plane of the tire is preferably 8 to 25 mm. By setting the thickness T1 to 8 mm or more, the wear resistance of the tire can be improved, while by setting the thickness T1 to 25 mm or less, the fuel efficiency is improved and the tire passes through the equatorial plane. This is because the amount of magnetic flux generated by the tread rubber is reduced and the power receiving efficiency can be improved.
Further, in the above case, the thickness T2 of the tread portion at the above 1/8 point is preferably 5 to 24 mm. By setting the thickness T2 to 5 mm or more, the wear resistance of the tire can be improved, while by setting the thickness T2 to 24 mm or less, the fuel efficiency is improved, and the above 1/8 point. This is because the amount of magnetic flux passing through the tire is hindered by the tread rubber and the power receiving efficiency can be improved.
Regarding the thickness of the tread, if there is a groove on the equatorial plane of the tire, a virtual line assuming that there is no groove shall be drawn, and if there is a groove at the above 1/8 point, it shall be considered. Let us consider by drawing a virtual line assuming that there is no groove.
Further, when referring to the relationship between T1 and T2, the thickness of the tread portion is the thickness measured in the normal direction of the line (or virtual line) forming the tread tread at the position.
If the thickness of the tread portion at the above 1/8 point (point P) differs between the half portions in the tread width direction with the tire equatorial plane CL as the boundary, the above 1/8 point (point P) on the inside when the vehicle is mounted. If the thickness of the tread portion in is smaller than the thickness of the tread portion at the above 1/8 point (point P) on the outside when the vehicle is mounted, it is generated diagonally outward from the road surface and on the inside when the vehicle is mounted. The above-mentioned action and effect can be efficiently obtained for the magnetic flux passing through the above 1/8 point (point P), while the tread at the above 1/8 point (point P) on the outside when mounted on a vehicle. If the thickness of the portion is smaller than the thickness of the tread portion at the above 1/8 point (point P) on the inside when the vehicle is mounted, it is generated diagonally inward from the road surface, and the above 1 on the outside when the vehicle is mounted. The above-mentioned action and effect can be efficiently obtained for the magnetic flux passing through the / 8 point (point P).

Alternatively, on the surface of the tread separated from the tread end TE inward in the tire width direction by 1/8 of the tread width TW in a cross-sectional view in the tire width direction in a state where the tire / wheel assembly 3 is filled with the specified internal pressure and no load is applied. When the point is set to 1/8 point (point P), in the above state, the thickness T1 of the tread portion 13 on the tire equatorial plane CL is the tread portion 13 at the above 1/8 point (point P). It is also preferable that the thickness is smaller than T2.
According to this, (for example, when the ring of the power transmission coil 41 is parallel to the road surface), the magnetic flux passing through the equator surface of the tire is less likely to be prevented from reaching the power reception coil 31 by the tread rubber, and power reception is performed. Efficiency can be improved. Further, the wear resistance of the tire can be ensured as compared with the case where the tread thickness is reduced over the entire width direction of the tire.
The above-mentioned effects can be obtained as long as the power transmission coil 41 and the power reception coil 31 are arranged so that at least a part of the magnetic flux can pass through the equatorial plane of the tire.
Further, in the tire 10, the thickness T1 of the tread portion 13 on the tire equatorial plane CL is 1/8 of the above in the above state with respect to the half portions on both sides in the tire width direction with the tire equatorial plane CL as the boundary. It can be made smaller than the thickness T2 of the tread portion 13 at the point (point P), or only in one half portion, in the above state, the thickness T1 of the tread portion 13 on the tire equatorial plane CL. However, the thickness of the tread portion 13 at the above 1/8 point (point P) can be made smaller than the thickness T2.
Here, the ratio T2 / T1 of the thickness T2 of the tread portion at the above 1/8 point to the thickness T1 of the tread portion on the equatorial plane of the tire is preferably 100 to 120%. By setting the ratio T2 / T1 to 100% or more, the wear resistance of the tire can be improved, while by setting the ratio T2 / T1 to 120% or less, the power receiving efficiency is further improved. Because it can be done. For the same reason, the ratio T2 / T1 is more preferably 103 to 115%.
Further, it is also preferable that the thickness of the tread portion gradually increases from the tire equatorial plane CL toward the above 1/8 point (point P). This is because the power receiving efficiency can be improved while preventing the occurrence of a rigidity step in the tire width direction.
It is also possible to make the thickness T1 smaller than the thickness T2 by providing a step portion in the thickness of the tread between the tire equatorial plane CL and the above 1/8 point (point P). In this case, it is preferable to provide a step with the main groove in the circumferential direction as a boundary (that is, to have no step in one land portion).
In the above case, the thickness T1 of the tread portion on the equatorial plane of the tire is preferably 8 to 25 mm. By setting the thickness T1 to 8 mm or more, the wear resistance of the tire can be improved, while by setting the thickness T1 to 25 mm or less, the fuel efficiency is improved and the tire passes through the equatorial plane. This is because the amount of magnetic flux generated by the tread rubber is reduced and the power receiving efficiency can be improved.
Further, in the above case, the thickness T2 of the tread portion at the above 1/8 point is preferably 8 to 30 mm. By setting the thickness T1 to 8 mm or more, the wear resistance of the tire can be improved, while by setting the thickness T2 to 30 mm or less, the fuel efficiency is improved, and the above 1/8 point. This is because the amount of magnetic flux passing through the tread rubber is reduced and the power receiving efficiency can be improved.
If the thickness of the tread portion at the above 1/8 point (point P) differs between the half portions in the tread width direction with the tire equatorial plane CL as the boundary, the above 1/8 point (point P) on the inside when the vehicle is mounted. If the thickness of the tread portion in is smaller than the thickness of the tread portion at the above 1/8 point (point P) on the outside when the vehicle is mounted, it is generated diagonally outward from the road surface and on the inside when the vehicle is mounted. The above-mentioned action and effect can be efficiently obtained for the magnetic flux passing through the above 1/8 point (point P), while the tread at the above 1/8 point (point P) on the outside when mounted on a vehicle. If the thickness of the portion is smaller than the thickness of the tread portion at the above 1/8 point (point P) on the inside when the vehicle is mounted, it is generated diagonally inward from the road surface, and the above 1 on the outside when the vehicle is mounted. The above-mentioned action and effect can be efficiently obtained for the magnetic flux passing through the / 8 point (point P).

The internal pressure of the tire / wheel assembly is preferably 120 to 200 kPa. By setting the internal pressure to 200 kPa or less, the ground contact area becomes large. When the ground contact area is small, a space is created between the tire and the road surface, and water, foreign matter, etc. enter between them to hinder the magnetic flux and reduce the power receiving efficiency. It is possible to improve the power receiving efficiency by eliminating the space between the road surface and preventing the magnetic flux from being hindered by water, foreign matter, or the like. Further, by setting the internal pressure to 200 kPa or less, the sidewall portion of the tire is easily bent, and the distance between the power receiving coil and the power transmission coil can be shortened, which also improves the power receiving efficiency. Further, according to the tire / wheel assembly of the present embodiment, the internal pressure is 120 kPa or more, and rolling resistance can be reduced to improve fuel efficiency.
Here, the internal pressure is more preferably 140 to 180 kPa. This is because the power receiving efficiency can be further improved while further improving the fuel efficiency.
Further, the internal pressure is more preferably 150 to 170 kPa. This is because the power receiving efficiency can be further improved while further improving the fuel efficiency.
It is preferable that the relational expressions (1) and / or (2) of SW and OD are satisfied when the above internal pressure is applied.

Alternatively, the internal pressure of the tire / wheel assembly is preferably more than 200 kPa and 400 kPa or less. By setting the internal pressure to more than 200 kPa, rolling resistance can be reduced and fuel efficiency can be improved. Further, by setting the internal pressure to 400 kPa or less, the ground contact area becomes large. When the ground contact area is small, a space is created between the tire and the road surface, and water, foreign matter, etc. enter between them to hinder the magnetic flux and reduce the power receiving efficiency. It is possible to improve the power receiving efficiency by eliminating the space between the road surface and preventing the magnetic flux from being hindered by water, foreign matter, or the like. Further, by setting the internal pressure to 400 kPa or less, the sidewall portion of the tire is easily bent, and the distance between the power receiving coil and the power transmission coil can be shortened, which also improves the power receiving efficiency.
Here, the internal pressure is more preferably 260 to 350 kPa. It is possible to further improve fuel efficiency while further improving power receiving efficiency. Further, the internal pressure is more preferably 300 to 320 kPa. It is possible to further improve fuel efficiency while further improving power receiving efficiency.
It is preferable that the relational expressions (1) and / or (2) of SW and OD are satisfied when the above internal pressure is applied.

(wheel)
Next, the configuration of the wheel 20 will be described. FIG. 3 is a cross-sectional view in the width direction of the wheel 20 according to the embodiment of the present invention.

As shown in FIG. 3, the wheel 20 has a cylindrical rim portion 21 and a disc portion 22 provided inside the rim portion 21 in the radial direction and supported and fixed to the hub 2A of the vehicle 2. ..

The rim portion 21 has a pair of flanges 23 (inner flange 23A, outer flange 23B), a pair of bead seats 24 (inner bead seat 24A, outer bead seat 24B), and wells 25 from the outside in the width direction of the wheel. I have. The bead portion 11 of the tire 10 is attached to the bead seat 24. The flange 23 extends from the bead seat 24 outward in the radial direction of the wheel and outward in the width direction of the wheel in order to support the bead portion 11 of the tire 10 from the side surface. The well 25 has a concave shape inward in the radial direction between the pair of bead seats 24 in order to facilitate the attachment / detachment of the tire. The well 25 has a bottom and an inclined surface connecting the bottom and the bead sheet 24. Further, the bead seat 24 is provided with a pair of humps 26 (inner hump 26A, outer hump 26B) inside the width direction of the wheel. The hump 26 projects radially outward of the wheel to prevent the tire bead from falling into the well 25.

The rim portion 21 can be made of, for example, a non-magnetic material.
Non-magnetic materials include paramagnetic and diamagnetic materials with low magnetic permeability. As the non-magnetic material, for example, a resin material containing a thermoplastic resin such as polyester and nylon, a thermosetting resin such as vinyl ester resin and unsaturated polyester resin, and other synthetic resins can be used. The resin material can further contain fibers such as glass, carbon, graphite, aramid, polyethylene, and ceramic as reinforcing fibers. As the non-magnetic material, not only resin but also any non-metal material including rubber, glass, carbon, graphite, aramid, polyethylene, ceramic and the like can be used. Further, as the non-magnetic material, a metal material containing a paramagnetic material such as aluminum or a diamagnetic material such as copper can be used. As a result, the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 can be prevented from being obstructed by the rim portion 21, and the power receiving efficiency can be improved.

Further, the rim portion 21 of the wheel 20 is provided with a valve 27 for filling the cavity of the tire 10 with a gas such as air when the tire 10 is mounted. The valve 27 can be made of, for example, the resin material described above. By configuring the valve 27 with the non-magnetic material described above, it is possible to prevent the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 from being obstructed by the valve 27.

The disk portion 22 has an annular mounting portion 22A constituting its radial inner end portion, and a plurality of spokes 22B extending radially outward from the mounting portion 22A. The mounting portion 22A is a portion to be coupled and fixed to the hub 2A of the vehicle 2 (see FIGS. 1 and 3), and is in the width direction of the wheel in order to insert a bolt or the like for fixing the hub 2A and the mounting portion 22A. It has a mounting hole that penetrates. The radial outer end of the wheel of the spokes 22B is integrally coupled to the end of the wheel radial inner surface of the rim portion 21.

The disk portion 22 may include, for example, a magnetic material having a high magnetic permeability (for example, a ferromagnetic material) such as metal or ferrite. As a result, the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 can be made less likely to be attenuated by the influence of the metal and other magnetic fields existing outside the tire / wheel assembly 3, and the power receiving efficiency can be improved. Can be done. For example, when the disc portion 22 is made of a resin material, the weight of the wheel 20 can be reduced.

The disc portion 22 of the wheel 20 further includes a wheel cover 28 that covers the outside of the spoke 22B in the width direction. The wheel cover 28 may include, for example, a magnetic material having a high magnetic permeability (for example, a ferromagnetic material) such as metal or ferrite. As a result, the magnetic field reaching the power receiving coil 31 from the power transmitting coil 41 can be made less likely to be attenuated by the influence of the metal and other magnetic fields existing outside the tire / wheel assembly 3, and the power receiving efficiency can be improved. Can be done.

The wheel 20 receives power supplied wirelessly from the tire radial outside of the tire 10 to the inside of the rim portion 21 in the tire radial direction, that is, in the space surrounded by the rim portion 21 and the disc portion 22. It is provided with an accommodating portion for accommodating (see FIGS. 1 and 4). For example, when the power receiving device 30 is attached to the hub 2A of the vehicle 2, the power receiving device 30 is accommodated in the accommodating portion of the wheel 20 by attaching the wheel 20 to the hub 2A of the vehicle 2.

<Power receiving coil>
Returning to FIG. 1, the power receiving device 30 is attached to, for example, the hub 2A of the vehicle 2, but the power receiving device 30 is not limited to this, and the power receiving device 30 is attached to the hub 2A of the vehicle 2 such as the drive shaft 2B. 30 can be attached to any position where the wheel 20 is housed inside the rim portion 21 of the wheel 20 in the tire radial direction. In this example, the power receiving device 30 is configured to be non-rotating with respect to the rotation of the tire 10 and the wheel 20.
In the present embodiment, the power receiving coil (secondary coil) 31 is attached to the outer peripheral surface of the bottom of the well 25, and four power receiving coils 31 are arranged on the circumference at equal intervals (interval d (mm)). ing. Therefore, in this example, the power receiving coil 31 is configured to rotate together with the rotation of the tire 10 and the wheel 20. At this time, the position of the power receiving coil 31 on the circumference changes with the rotation of the tire 10 and the wheel 20, but the power receiving coil 31 is in a state where the tire / wheel assembly 3 is located above the power transmission device 40. At least at a certain tire rotation angle, the tires are arranged so as to face the transmission coil 41. As a result, when the tire 10 is located on the road surface above the power transmission coil 41 and the power transmission coil 41 and the power reception coil 31 face each other, an electromotive force is generated in the power reception coil 31 based on the AC magnetic field generated by the power transmission coil 41. It is generated, and current flows and power is supplied. The power receiving coil 31 is formed in an annular shape as a whole, and is arranged so that the axial direction of the ring is substantially perpendicular to the road surface. The power receiving coil 31 is wound around a core such as a ferrite core to form an annular shape as a whole, but is not limited to this, and an electromotive force is generated based on an alternating magnetic field such as a coil spring or an air core coil. It can be any coil that can be generated.
Here, the power receiving coil 31 may be attached to the inner peripheral surface of the bottom of the well 25 as long as it can face the power transmission coil 41 when the tire 10 is located on the road surface above the power transmission coil 41. Alternatively, it can be attached to the inner peripheral surface or the outer peripheral surface of another portion of the rim portion 21. In this case as well, the power receiving coil 31 rotates with the rotation of the tire 10 and the wheel 20. Alternatively, it can be mounted inside the tire / wheel assembly 3. In this case, the power receiving coil 31 may be configured to be non-rotating with respect to the rotation of the tire 10 or the wheel 20, or for example, a core protruding into the tire cavity fixed to the wheel 20 may be provided. Therefore, the power receiving coil 31 can be attached to the core so that the power receiving coil 31 rotates with the rotation of the tire 10 and the wheel 20.
The number of power receiving coils 31 is not particularly limited. For example, when a continuous power receiving coil 31 is used on one circumference, the tire 10 is located on the road surface above the power transmission coil 41. In addition, continuous power supply is possible during the rolling of the tire, or if the total size of the power receiving coil 31 is reduced by dividing the tire into a plurality of parts, the weight increase due to the power receiving coil 31 can be suppressed and the fuel consumption can be reduced. The sex can be improved. In the present embodiment, four power receiving devices 30 are included corresponding to the above four power receiving coils 31, but the number of power receiving devices 30 is also an arbitrary number according to the number of power receiving coils 31 and the like. The number of power receiving devices 30 can be different from the number of power receiving coils 31.

In this example, the power receiving device 30 includes a power conversion circuit 32, a power storage unit 33, and a control unit 34. The power conversion circuit 32 converts the power generated in the power receiving coil 31 into DC power, and supplies the DC power to the power storage unit 33 or another in-vehicle device included in the vehicle 2 via a conductive wire or the like. The power storage unit 33 stores the electric power generated in the power receiving coil 31. The power storage unit 33 is, for example, a capacitor, but is not limited to this, and can be any power storage device such as a storage battery. When the power storage unit 33 is a capacitor, charging / discharging can be performed in a shorter time than that of a storage battery. Therefore, the power storage unit 33, which is a capacitor, is advantageous in a situation where high responsiveness is required such that the power generated in the power receiving coil 31 is stored when the vehicle 2 travels on the power transmission device 40 provided on the road. Is. The control unit 34 may include one or more processors that provide processing for controlling each function of the power receiving device 30. The control unit 34 can be a general-purpose processor such as a CPU (Central Processing Unit) that executes a program that defines a control procedure, or a dedicated processor that specializes in processing each function. The control unit 34 can include a storage means for storing a program or the like, and an arbitrary means used for controlling a power receiving device 30 such as a communication means for communicating with an external electronic device by wire or wirelessly.
When the power receiving coil 31 is configured to rotate with the rotation of the tire 10 and the wheel 20 as in the present embodiment, the electric power generated in the power receiving coil 31 is transmitted to the power receiving coil 31 via, for example, a slip ring. It can be transmitted to the power conversion circuit 32 or the like. Alternatively, the power generated in the power receiving coil 31 is transmitted to the first relay coil (by wire), and the magnetic field generated by the current flowing through the first relay coil passes through the second relay coil to the second relay coil. A current flows and can be transmitted from the second relay coil to the power conversion circuit 32 or the like. In this case, the first relay coil and the second relay coil are also configured to rotate with the rotation of the tire 10 and the wheel 20, and in the case of the above example, the relay coil can be attached to the outer peripheral surface of the well 25 as an example. ..
On the other hand, when the power receiving coil 31 does not rotate with respect to the rotation of the tire 10 or the wheel 20 (for example, when the power receiving coil 31 is attached to the hub 2A), the power storage unit 33 directly from the power receiving coil 31. Etc. can be transmitted. In this case, in particular, the carcass 14 is made of the above-mentioned non-magnetic material, the belt cord is made of the above-mentioned non-magnetic material, and the rim portion 21 of the wheel 20 is made of the above-mentioned non-magnetic material, which suppresses a decrease in power receiving efficiency. It is preferable from the viewpoint of

FIG. 4 is a schematic view schematically showing a wireless power receiving system having a tire / wheel assembly of a modified example according to an embodiment of the present invention with a cross section in the tire width direction.
In the example shown in FIG. 4, the tire / wheel assembly 1 includes an in-wheel motor 4. A power receiving device 30 is attached to the in-wheel motor 4.
As shown in FIG. 4, the power receiving device 30 can be attached to the tire 10 or the wheel 20 so that the tire 10 or the wheel 20 does not rotate when the tire 10 or the wheel 20 rotates (in the illustrated example, the cover of the hub 2A or the like).
In this case, in particular, only one power receiving device 30 (power receiving coil 31) can be arranged at a position facing the road surface. On the other hand, as shown in FIG. 1, when the power receiving device 30 is mounted at a position where the tire 10 and the wheel 20 rotate with rotation, one or more power receiving devices 30 (power receiving coil 31) are installed. , It is preferable to install the wheel 20 continuously or intermittently in the circumferential direction.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments. For example, in the present invention, the vehicle 2 has been described as being an automobile, but this is not the case. Vehicle 2 includes, in addition to automobiles such as passenger cars, trucks, buses, and two-wheeled vehicles, agricultural vehicles such as tractors, construction or construction vehicles such as dump trucks, electric bicycles, and power sources such as motors such as electric wheelchairs. It may include any vehicle that drives wheels and tires. Further, in addition to the one in which the vehicle itself is electrically driven, it may be used as a power source for using electric power in the vehicle.

Further, for example, in the present invention, the tire has been described as being filled with air, but the present invention is not limited to this. For example, the tire can be filled with a gas such as nitrogen. Further, for example, the tire can be filled with any fluid including not only gas but also liquid, gel-like substance, powder or granular material and the like.

Further, for example, in the present invention, the tire has been described as being a tubeless tire provided with an inner liner, but the present invention is not limited to this. For example, the tire may be a tube type tire provided with a tube.

Further, for example, in the present invention, the tire may be a non-pneumatic tire. In this case as well, the power receiving coil may be arranged at a position where it can face the power transmission coil.

In the present invention, it is particularly preferable to use a tire having a ground contact width of 120 mm or more.

1: Wireless power receiving system, 2: Vehicle,
2A: Hub, 2B: Drive shaft,
3: Tire / wheel assembly, 4: In-wheel motor,
10: Tire, 11: Bead part,
12: sidewall part, 13: tread part,
14: Carcass, 14A: Carcass main body, 14B: Carcass folded part,
15: Belt, 16: Inner liner,
17: Circumferential main groove,
20: Wheel, 21: Rim part,
22: Disc part, 22A: Mounting part, 22B: Spokes,
23: Flange, 24: Bead sheet, 25: Well,
26: Hump, 27: Valve, 28: Wheel cover,
30: Power receiving device, 31: Power receiving coil,
32: Power conversion circuit, 33: Power storage unit, 34: Control unit,
40: Power transmission device, 41: Power transmission coil

Claims (3)

A tire / wheel assembly comprising a tire having a tread portion and a wheel having a rim portion.
The tire is attached to the rim portion and is mounted on the rim portion.
The tire / wheel assembly includes a power receiving coil.
The tread portion has a circumferential main groove extending in the circumferential direction of one or more tires.
The negative ratio of the circumferential main groove of one half of the tread portion in the tire width direction on the inner side when mounted on the vehicle is the negative rate of the other half in the tire width direction of the tread portion on the outer side when mounted on the vehicle. A tire / wheel assembly characterized in that it is larger than the negative ratio of the circumferential main groove. The tire / wheel assembly according to claim 1, wherein the groove width of the circumferential main groove is 3 mm or more. The tire / wheel assembly according to claim 1 or 2, wherein the thickness of the tread portion is 8 to 25 mm.

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