JP5552910B2 - Tire / wheel system - Google Patents

Description

  The present invention relates to a tire / wheel system that combines a tire and a wheel.

  A pneumatic tire is known as a tire that is widely used in vehicles such as automobiles. The pneumatic tire has a problem that air or nitrogen gas filled therein is reduced due to puncture or the like. In recent years, non-pneumatic tires that are not filled with gas have been studied.

JP 2008-074345 A JP 2006-117057 A

  Examples of the non-pneumatic tire include those described in Patent Documents 1 and 2. It is an object of the present invention to provide a new tire / wheel system having a non-pneumatic tire.

  Means for solving the above-described problems are a first annular body that is a cylindrical member, and a cylindrical member that is disposed on the radially outer side of the first annular body, and has a rubber layer on the outer peripheral portion. A second annular body, interposed between the first annular body and the second annular body, extending in a circumferential direction of the first annular body and the second annular body, and against compression And a repulsive force generating member that generates a repulsive force.

  In the above-described means, a first convex portion projecting radially outward from the outer peripheral portion of the first annular body, a radially inner side projecting from an inner peripheral portion of the second annular body, and the first It is preferable to have a second convex part that engages with the convex part to restrict relative movement of both the first annular body and the second annular body in a direction parallel to the central axis.

  In the above-described means, the repulsive force generating member includes at least one first repulsive force generating member interposed between an outer peripheral portion of the first annular body and an inner peripheral portion of the second annular body, and the first It is preferable to have at least one second repulsive force generating member interposed between the convex portion and the second convex portion.

  In the above-described means, the first annular body is preferably divided into two or more in a direction parallel to the central axis.

  In the above-described means, it is preferable that each of the first convex portion and the second convex portion is an annular plate member.

  In the above-described means, the first annular body has two or more first convex portions in a direction parallel to the central axis, and the second annular body is the first annular body in a direction parallel to the central axis. It is preferable to have two or more two convex portions.

  In the above-described means, it is preferable that an end portion on the radially outer side of the first convex portion is radially outer side than an end portion on the radially inner side of the second convex portion.

  In the above-mentioned means, it is preferable that at least one of the first repulsive force generating members is a tube extending in the circumferential direction, and has a valve for filling the tube with gas.

  In the above-described means, the first repulsive force generating member is a tube extending in the circumferential direction and a solid member extending in the circumferential direction, and in the radial direction of the first annular body. The dimensions of the tube are preferably larger.

  In the above-mentioned means, it is preferable that at least one second repulsive force generating member is a tube extending in the circumferential direction, and has a valve for filling the tube with gas.

FIG. 1 is a meridian cross-sectional view showing the tire / wheel system according to the first embodiment. FIG. 2 is a cross-sectional view of a tire / wheel system according to a first modification of the first embodiment. FIG. 3 is a meridional sectional view of a tire / wheel system according to a second modification of the first embodiment. FIG. 4 is a meridional sectional view showing the tire / wheel system according to the second embodiment. FIG. 5 is a meridional sectional view showing the tire / wheel system according to the third embodiment. FIG. 6 is a meridional sectional view showing the tire / wheel system according to the fourth embodiment.

  DESCRIPTION OF EMBODIMENTS Hereinafter, modes (embodiments) for carrying out the present invention will be described in detail with reference to the drawings. The present invention is not limited by the contents described in the following embodiments. The constituent elements described below include those that can be easily assumed by those skilled in the art and those that are substantially the same. Furthermore, the constituent elements described below can be appropriately combined.

(Embodiment 1)
FIG. 1 is a meridian cross-sectional view showing the tire / wheel system according to the first embodiment. The meridian section is a plane parallel to the rotation axis (Y axis) of the tire / wheel system 10 and including the rotation axis (Y axis) when the tire / wheel system 10 is cut. In the meridional section, since the tire / wheel system 10 is an axis object with respect to the rotation axis (Y axis), in the present embodiment, one of the objects is illustrated.

  The tire / wheel system 10 rotates about a central axis (Y axis) as a rotation axis. The Y axis is the central axis and rotation axis of the tire / wheel system 10. An axis that is orthogonal to the Y axis that is the central axis (rotation axis) of the tire / wheel system 10 and that is parallel to the road surface on which the tire contacts the ground is an X axis, and an axis that is orthogonal to the Y axis and the X axis is a Z axis. The direction parallel to the Y axis is the width direction of the tire / wheel system 10. The direction passing through the Y axis and perpendicular to the Y axis is the radial direction of the tire / wheel system 10. The circumferential direction around the Y axis is the circumferential direction of the tire / wheel system 10. The tire equatorial plane RP is a plane that is orthogonal to the rotation axis (Y axis) of the tire / wheel system 10 and passes through the center in the width direction of the tire / wheel system 10. The tire equator line is a line on the tire equator plane where the outer peripheral surface of the tire / wheel system 10 intersects the equator plane.

  The tire / wheel system 10 shown in FIG. 1 includes a first annular body 11, a second annular body 21, and a repulsive force generating member 31. The central axes of the first annular body 11 and the second annular body 21 are common to the rotation axis (Y axis) of the tire / wheel system 10. The first annular body 11 is a cylindrical member, and is connected to the hub 13 via the spoke 12. The hub 13 is attached to the axle of the vehicle. The first annular body 11 may be connected to the hub 13 by a disk instead of the spoke 12. A member that connects the first annular body 11 and the hub 13 is referred to as a connecting member.

  In the present embodiment, the first annular body 11 is divided into two members, a first member 11a and a second member 11b, in a direction parallel to the central axis (Y axis). The first member 11a is fastened to the second member 11b by a bolt 19. Such a structure facilitates assembly and disassembly of the tire / wheel system 10. Note that the number of divisions of the first annular body 11 is not limited to 2, and may be 3 or more. Moreover, although the 1st member 11a and the 2nd member 11b are couple | bonded by the volt | bolt 19, the means to couple | bond both is not limited to this.

  In this embodiment, although the 1st annular body 11 is manufactured with a metal, it is not limited to this. For example, the first annular body 11 may be made of fiber reinforced plastic such as CFRP (Carbon Fiber Reinforced Plastics) or GFRP (Glass Fiber Reinforced Plastics). In the present embodiment, the first annular body 11 is made of an aluminum alloy. A metal material is not limited to this, For example, steel (carbon steel, stainless steel, etc.) may be sufficient. An aluminum alloy is preferable because it has a smaller specific gravity than steel and can reduce the mass of the tire / wheel system 10. In the present embodiment, the second member 11 b of the first annular body 11 is manufactured integrally with the spoke 12 and the hub 13.

  The 1st annular body 11 has a pair of 1st convex parts 16a and 16b which protrude toward the radial direction outer side from the outer peripheral part 11I. The 1st convex part 16a protrudes from the 1st member 11a, and the 1st convex part 16b protrudes from the 2nd member 11b. In the present embodiment, the first convex portion 16a is manufactured integrally with the first member 11a, and the first convex portion 16b is manufactured integrally with the second member 11b. Or by bolting or the like. For example, if the 1st convex part 16a and the 1st member 11a are manufactured as a different body, the 1st member 11a and the 2nd member 11b can be manufactured integrally by casting, forging, etc. In this case, when the tire / wheel system 10 is assembled or disassembled, the first convex portion 16a may be attached to and detached from the first member 11a.

  The first annular body 11 has a pair of grooves 11Sa and 11Sb in the outer peripheral portion 11I. One groove 11Sa has the first member 11a, and the other groove 11Sb has the second member 11b. The grooves 11Sa and 11Sb are provided continuously in the circumferential direction of the first annular body 11, but may be provided intermittently. The grooves 11Sa and 11Sb are provided at positions facing second convex portions 28a and 28b described later. For example, stoppers 47a and 47b made of resin are attached to the grooves 11Sa and 11Sb, respectively.

  The second annular body 21 is a cylindrical member and is disposed on the radially outer side of the first annular body 11. In the present embodiment, the second annular body 21 is made of metal in the same manner as the first annular body 11, but is not limited thereto. For example, the second annular body 21 may be made of fiber reinforced plastic such as CFRP (Carbon Fiber Reinforced Plastics) or GFRP (Glass Fiber Reinforced Plastics). In this embodiment, although the 1st annular body 11 is manufactured with an aluminum alloy, it is not limited to this. The reason is the same as that for the first annular body 11.

  The second annular body 21 has a rubber layer 22 on the outer peripheral portion 23. The second annular body 21 and the rubber layer 22 correspond to the tire of the tire / wheel system 10. The rubber layer 22 corresponds to the tread portion of the tire of the tire / wheel system 10. The rubber layer 22 covers the outer peripheral portion 23 of the annular second annular body 21 by one turn in the circumferential direction. That is, the rubber layer is a rubber ring that is fitted into the outer peripheral portion 23 of the second annular body 21. The rubber layer 22 may be laminated with a plurality of types of rubber in the radial direction. Since the rubber layer 22 is solid rubber, the second annular body 21 and the rubber layer 22 corresponding to the tire of the tire / wheel system 10 correspond to a non-pneumatic tire.

  The surface of the rubber layer 22, that is, the outermost surface in the radial direction of the tire / wheel system 10 is a surface (step surface) 24 that directly contacts the road surface. In the present embodiment, the rubber layer 22 and the second annular body 21 are fixed by, for example, an adhesive. With such a structure, force can be transmitted between the second annular body 21 and the rubber layer 22. In the present embodiment, the outer peripheral portion 23 of the second annular body 21 has minute irregularities. This minute unevenness increases the surface area of the bonding region, which is preferable because the bonding strength between the second annular body 21 and the rubber layer 22 can be improved. The means for fixing the annular body 21 and the rubber layer 22 is not limited to the adhesive. For example, the annular body 21 and the rubber layer 22 may be vulcanized and bonded by adding an adhesive component to rubber and vulcanizing.

In the present embodiment, the rubber layer 22 has a plurality of circumferential grooves 25 extending along the circumferential direction. For this reason, the tread 24 has a plurality of land portions 26 that are partitioned by a plurality of circumferential grooves 25 and extend along the circumferential direction. Each land portion 26 of the tread surface 24 may be provided with a lug groove that intersects the circumferential groove 25. In the present embodiment, the dimension in the width direction of the rubber layer 22 is substantially the same as the dimension in the width direction of the second annular body 21, but the former is preferably less than or equal to the latter. In this way, since the contact pressure at both ends in the width direction of the rubber layer 22 can be suppressed from being excessively increased, uneven wear of the rubber layer 22 can be suppressed. The rubber layer 22 includes synthetic rubber, natural rubber, or a rubber material obtained by mixing them, and carbon, SiO _2, or the like that is added to the rubber material as a reinforcing material.

  The second annular body 21 has a pair of second convex portions 28 a and 28 b that protrude radially inward from the inner peripheral portion 27. In the present embodiment, the second convex portions 28a and 28b are manufactured integrally with the second annular body 21, but may be integrated by means such as welding or bolting after being manufactured separately. .

  As shown in FIG. 1, in this embodiment, the 1st convex parts 16a and 16b which the 1st annular body 11 has are arrange | positioned rather than the 2nd convex parts 28a and 28b which the 2nd annular body 21 has in the width direction outer side. The In addition, the 2nd convex parts 28a and 28b which the 2nd annular body 21 has may be arrange | positioned rather than the 1st convex parts 16a and 16b which the 1st annular body 11 has in the width direction outer side. Since it is such a structure, the 2nd convex parts 28a and 28b engage with the 1st convex parts 16a and 16b, respectively, and the central axis (Y axis) of the 1st annular body 11 and the 2nd annular body 21 and The relative movement of the first annular body 11 and the second annular body 21 in the parallel direction, that is, the width direction is restricted. With such a structure, separation between the first annular body 11 and the second annular body 21 is avoided.

  In the present embodiment, the gaps 48 and 49 are adjusted in consideration of thermal expansion so that the first protrusions 16a and 16b and the second protrusions 28a and 28b can move in the radial direction. In addition, if there is a gap between the first protrusions 16a and 16b and the second protrusions 28a and 28b, there is a possibility that sound or vibration is generated due to contact between the two. For this reason, you may interpose vibration-proof materials, such as rubber | gum and felt, between the 1st convex parts 16a and 16b and the 2nd convex parts 28a and 28b. If it does in this way, when the 1st convex parts 16a and 16b and the 2nd convex parts 28a and 28b contact, generation of sound and vibration can be controlled.

  The second annular body 21 has a higher elastic modulus than the rubber layer 22. Generally, the elastic modulus (longitudinal elastic modulus) of the rubber material is about 0.01 GPa to 0.1 GPa, but the elastic modulus (longitudinal elastic modulus) of the second annular body 21 is about 40 GPa to 200 GPa depending on the material. is there. Thus, the elastic modulus of the second annular body 21 is several tens of times or more than the elastic modulus of the rubber layer 22. The tire / wheel system 10 uses, as the second annular body 21, an elastic modulus that is several hundred times greater than that of the rubber layer 22.

  In the present embodiment, the tire / wheel system 10 uses the frictional force between the first annular body 11 and the repulsive force generating member 31 and the frictional force between the repulsive force generating member 31 and the second annular body 21. Thus, force is transmitted between the first annular body 11 and the second annular body 21. For this reason, frictional heat resulting from the frictional force is generated. This frictional heat is transmitted to the first annular body 11 and the second annular body 21. The frictional heat transmitted to the second annular body 21 is released from the surface of the second annular body 21 into the atmosphere. In this embodiment, since the 2nd annular body 21 has the some heat radiating hole 29, the thermal radiation area of frictional heat improves. With such a structure, the tire / wheel system 10 can efficiently release frictional heat into the atmosphere, so that the thermal expansion of the second annular body 21 can be suppressed and the function can be stably exhibited.

  The second annular body 21 has convex portions 37 a and 37 b that protrude radially inward from the inner peripheral portion 27. The convex portions 37 a and 37 b are disposed on both sides in the width direction of the repulsive force generating member 31. The protrusions 37a and 37b restrict the movement of the repulsive force generating member 31 in the width direction. Moreover, since the 2nd annular body 21 has the convex parts 37a and 37b, the surface area of the inner peripheral part 27 can be enlarged. With such a structure, the tire / wheel system 10 can more efficiently release frictional heat from the second annular body 21 into the atmosphere. As will be described later, since the repulsive force generating member 31 extends in the circumferential direction of the tire / wheel system 10, it is preferable that the convex portions 37a and 37b also extend in the circumferential direction. . The convex portions 37a and 37b do not have to be provided continuously in the circumferential direction, and may be provided intermittently in the circumferential direction.

  The repulsive force generating member 31 is interposed between the first annular body 11 and the second annular body 21 and extends in the circumferential direction of the first annular body 11 and the second annular body 21. The repulsive force generating member 31 is a member that generates a repulsive force against compression. The tire / wheel system 10 includes at least one repulsive force generating member 31. The repulsive force generating member 31 is in contact with both the first annular body 11 and the second annular body 21. The repulsive force generating member 31 has a circular cross-sectional outer shape, but its diameter is preferably larger than the distance when the first annular body 11 and the second annular body 21 are farthest from each other. With such a structure, when the first annular body 11 or the second annular body 21 rotates, the repulsive force generating member 31 generates a frictional force between the first annular body 11 and between the second annular body 21. To do. As a result, the tire / wheel system 10 can transmit force between the first annular body 11 and the second annular body 21 via the repulsive force generating member 31.

  At the same time, when the repulsive force generating member 31 is compressed and deformed in the radial direction of the tire / wheel system 10, a repulsive force is generated. Thereby, the repulsive force generating member 31 can support the load acting on the tire / wheel system 10. Furthermore, the impact input to the tire / wheel system 10 is absorbed by the repulsive force generating member 31 being elastically deformed. That is, the repulsive force generating member 31 functions as a vertical spring of the tire / wheel system 10. The repulsive force generating member 31 preferably has a spring constant necessary as a longitudinal spring of the tire / wheel system 10 in the compression direction. For example, the spring constant of the repulsive force generating member 31 is preferably 50 N / mm or more and 500 N / mm or less.

  In the present embodiment, the repulsive force generating member 31 is, for example, a tube made of rubber or a flexible resin. When the repulsive force generating member 31 is made of rubber, for example, a rubber material similar to the rubber layer 22 described above can be used. The repulsive force generating member 31 may be reinforced with fibers. Since the repulsive force generating member 31 transmits force between the first annular body 11 and the second annular body 21, it is preferable that the repulsive force generating member 31 is reinforced with fibers because durability is improved. The repulsive force generating member 31 is not limited to a tube, and may be an annular member made of solid rubber or resin. Further, the cross-sectional shape of the repulsive force generating member 31 is not limited to a circular shape.

  The material of the repulsive force generating member 31 is not particularly limited, but it is preferable that the material is mainly rubber or resin. In general, the elastic modulus of the polymer material is several tenths or less compared to a metal material or a fiber reinforced plastic that is a material of the first annular body 11 and the second annular body 21. For this reason, when the repulsive force generating member 31 is sandwiched between the first annular body 11 and the second annular body 21, the repulsive force generating member 31 is deformed to have a contact area with the surfaces of the first annular body 11 and the second annular body 21. growing. As a result, the repulsive force generating member 31 can transmit the force more efficiently between the first annular body 11 and the second annular body 21.

  In the present embodiment, when the repulsive force generating member 31 makes one turn in the circumferential direction of the first annular body 11 and the second annular body 21, it is preferable to use an endless tube (the same applies to the same example below). The internal space 31I of the repulsive force generating member 31 is filled with gas (air or nitrogen) at a predetermined pressure. By adjusting the pressure of the gas filled in the repulsive force generating member 31, the spring constant of the repulsive force generating member 31 in the radial direction of the tire / wheel system 10 (the spring constant in the compression direction) can be changed. As a result, the diamond / wheel system 10 is changed in longitudinal rigidity. Thus, when a tube is used for the repulsive force generating member 31, there is an advantage that the longitudinal rigidity of the tire / wheel system 10 can be easily changed. In this case, since the tube as the repulsive force generating member 31 can be specialized in spring characteristics and gas leakage performance, the design of the tire / wheel system 10 becomes relatively easy. Further, by adjusting the pressure of the gas filled in the repulsive force generating member 31, the magnitude of the friction force generated between the repulsive force generating member 31 and the first annular body 11 and the second annular body 21 is adjusted. it can.

  In the present embodiment, the repulsive force generating member 31 has a valve 38 for filling or discharging gas in the internal space 31I. The valve 38 is installed in a state where the valve 38 is inserted through the through hole 39 of the first annular body 11, but the mode of installation of the valve 38 is not limited to this. With such a structure, the pressure of the gas filled in the repulsive force generating member 31 via the valve 38 in a state where the repulsive force generating member 31 is disposed between the first annular body 11 and the second annular body 21. Can be adjusted. As a result, maintenance / inspection, gas replenishment, and adjustment of the longitudinal rigidity of the tire / wheel system 10 are facilitated.

  When the tire / wheel system 10 rolls in a state where it is attached to the vehicle, the second annular body 21 and the first annular body 11 are displaced relative to the radial direction due to a load from the vehicle, an impact from the road surface, or the like. To do. This displacement is absorbed by the deformation of the repulsive force generating member 31 as described above. At this time, if the displacement is large, the end portions 43 and 45 of the first convex portions 16a and 16b of the first annular body 11 collide with the second annular body 21 or the second convexity of the second annular body 21. There is a possibility that the end portions 44 and 46 of the portions 28 a and 28 b may collide with the first annular body 11. Therefore, as described above, the tire / wheel system 10 includes the stoppers 47a and 47b at positions facing the end portions 44 and 46 of the second convex portions 28a and 28b.

  Even if the end portions 44 and 46 of the second convex portions 28a and 28b collide with the stoppers 47a and 47b due to the displacement, the stoppers 47a and 47b are made of resin and absorb the impact. The distance between the end portions 44 and 46 of the second convex portions 28a and 28b and the stoppers 47a and 47b is smaller than the distance between the end portions 43 and 45 of the first convex portions 16a and 16b and the second annular body 21. Keep it. With such a structure, the end portions 43 and 45 of the first convex portions 16a and 16b directly collide with the second annular body 21, or the end portions 44 and 46 of the second convex portions 28a and 28b are collided with the first annular body 11. Therefore, noise caused by the collision can be suppressed. Further, deformation of the first convex portions 16a and 16b and the second convex portions 28a and 28b can be suppressed.

  Further, when a tube is used as the repulsive force generating member 31 and the inside is filled with gas, if the repulsive force generating member 31 is damaged or the like, the repelling force generating member 31 may leak the gas. If gas leaks from the repulsive force generating member 31, the repulsive force generating member 31 may not be able to support the load acting on the tire / wheel system 10. In such a case, the end of the second convex portions 28a and 28b Since the parts 44 and 46 are in contact with the stoppers 47a and 47b, the impact when the first annular body 11 is in contact with the second annular body 21 can be suppressed. Furthermore, when the end portions 44 and 46 of the second convex portions 28a and 28b come into contact with the resin stoppers 47a and 47b, a frictional force is generated between them. For this reason, force can be transmitted between the 2nd convex parts 28a and 28b and stoppers 47a and 47b. As a result, even if the repulsive force generating member 31 cannot support the load of the tire / wheel system 10 and the force cannot be transmitted between the first annular body 11 and the second annular body 21, the vehicle travels for a certain distance. can do.

  The stoppers 47a and 47b also have a run flat function. The positions where the stoppers 47a and 47b are provided are not limited to the example of this embodiment. However, as in the present embodiment, the stoppers 47a and 47b are arranged in a space surrounded by the first convex portions 16a and 16b, the second convex portions 28a and 28b, the first annular body 11 and the second annular body 21. Thus, the amount of ultraviolet rays irradiated to the stoppers 47a and 47b can be drastically reduced. Since the stoppers 47a and 47b are resins easily deteriorated by ultraviolet rays, the effect of drastically reducing the amount of ultraviolet irradiation is very effective for extending the life of the stoppers 47a and 47b.

  The repulsive force generating member 31 is disposed in a space surrounded by the first convex portions 16 a and 16 b, the second convex portions 28 a and 28 b, the first annular body 11 and the second annular body 21. For this reason, the tire / wheel system 10 can drastically reduce the amount of ultraviolet rays applied to the repulsive force generating member 31. Since the repulsive force generating member 31 is made of rubber, resin, or the like that is easily deteriorated by irradiation with ultraviolet rays, the tire / wheel system 10 extremely effectively suppresses a decrease in the durability of the repulsive force generating member 31 for a long time. The function can be demonstrated over.

  Since the conventional pneumatic tire is a composite material of a fiber material such as a carcass or a belt and rubber, the rigidity in the meridional section is low. On the other hand, in the tire / wheel system 10, the rubber layer 22 is supported by the second annular body 21 with the second annular body 21, which is a cylindrical structure made of a metal material or fiber-reinforced plastic, as a skeleton. The 2nd annular body 21 is a cyclic | annular structure with which the plate-shaped member continued in the circumferential direction, and the rigidity in a meridian cross section is high from the surface of a shape. For this reason, the tire / wheel system 10 has higher rigidity in the meridional section than the conventional pneumatic tire. Moreover, since the 2nd annular body 21 has the high rigidity in a meridional section, the shape in the meridional section of the outer peripheral part 23 of the 2nd annular body 21 can also maintain a high precision. For this reason, compared with the conventional pneumatic tire, the tire / wheel system 10 is easy to keep the shape of the contact surface in a predetermined shape.

  Moreover, since the 2nd annular body 21 is manufactured with a metal, a fiber reinforced plastic, etc., the thing of various shapes can be obtained compared with the combination of a fiber material. For this reason, the tire / wheel system 10 is relatively easy to adjust to a desired ground contact shape by changing the shape of the outer peripheral portion 23 of the second annular body 21 in the meridional section. As a result, the tire / wheel system 10 can improve the turning performance by making the contact pressure distribution in the width direction uniform or increasing the contact length (the length of the contact surface in the circumferential direction), for example.

  Further, the tire / wheel system 10 can be easily manufactured as compared with a conventional pneumatic tire because there is no carcass or belt layer. That is, the tire / wheel system 10 is completed by attaching the ring-shaped rubber layer 22 to the outer peripheral portion 23 of the second annular body 21 and then assembling the second annular body 21 to the first annular body 11. For this reason, when manufacturing the tire / wheel system 10, the manufacturing process can be greatly automated as compared with a conventional pneumatic tire.

  In the tire / wheel system 10, the second annular body 21 is disposed on the radially outer side of the repulsive force generating member 31, and a rubber layer 22 that is in contact with the road surface is attached on the radially outer side of the second annular body 21. For this reason, even if the rubber layer 22 is damaged, the influence of the damage to the rubber layer is prevented by the second annular body 21. As a result, the repulsive force generating member 31 arranged on the radially inner side of the second annular body 21 is hardly affected by the damage, and is excellent in running performance.

  The rubber layer 22 of the tire / wheel system 10 only needs to correspond to the cap tread and undertread of a conventional pneumatic tire. For this reason, the tire / wheel system 10 can reduce the amount of rubber used compared with the conventional pneumatic tire. As a result, the tire / wheel system 10 can reduce rolling resistance. Further, when the rubber layer 22 is worn, the tire / wheel system 10 can recover the rubber layer 22 together with the second annular body 21, remove the rubber layer 22, and reuse the second annular body 21. It is also easy to remove the rubber layer 22 of the second annular body 21 with the collected rubber layer 22 and attach a new rubber layer 22 to the second annular body 21 (retreading). Thus, the tire / wheel system 10 can reduce the environmental load. Furthermore, since only the rubber layer 22 can be replaced, the second annular body 21 can be replaced with a rubber layer 22 having a different tread pattern or a different compound without changing the second annular body 21.

  Next, an example of a procedure for combining the first annular body 11, the second annular body 21, and the repulsive force generating member 31 will be described. As shown in FIG. 1, the first annular body 11 is assembled by joining two members of a first member 11 a and a second member 11 b with a plurality of bolts 19. First, in a state where the first member 11a and the second member 11b are divided, the second annular body 21 in which the repulsive force generating member 31 is attached to the inner peripheral portion 27 is assembled to the second member 11b. Next, after assembling the first member 11 a to the second member 11 b, both are fastened by a plurality of bolts 19. In the tire / wheel system 10, the first protrusions 16 a and 16 b included in the first annular body 11 are arranged on the outer side in the width direction than the second protrusions 28 a and 28 b included in the second annular body 21 (the reverse is also possible). However, the 1st annular body 11 can be easily and reliably assembled by setting it as the division structure in the width direction.

(First modification)
FIG. 2 is a cross-sectional view of a tire / wheel system according to a first modification of the first embodiment. FIG. 2 shows a state when the tire / wheel system is cut along the equator plane. In this modification, the repulsive force generating member 31A extends in the circumferential direction of the tire / wheel system 10A, but a plurality of repulsive force generating members 31A are disposed discontinuously in the circumferential direction.

  As shown in FIG. 2, from the outer peripheral part 11I of the first annular body 11A, a first engaging part 14 that engages with the repulsive force generating member 31A in the circumferential direction protrudes outward in the radial direction. Further, a second engaging portion 50 that engages with the repulsive force generating member 31A protrudes radially inward from the inner peripheral portion 27 of the second annular body 21A. Each repulsive force generating member 31 </ b> A is disposed between the first engaging portion 14 and the second engaging portion 50.

  With such a structure, in addition to the frictional force between the repulsive force generating member 31A and the first annular body 11A and the second annular body 21A, the first engaging portion 14, the repulsive force generating member 31A, and the second engaging portion. Force can be transmitted even between 50. As a result, the tire / wheel system 10A can transmit the force more reliably between the first annular body 11A and the second annular body 21A, and can also reduce the loss generated in the force transmission.

  Furthermore, in this modification, a plurality of repulsive force generating members 31A are arranged in the circumferential direction. For example, even if one repulsive force generating member 31A loses the force transmission function and the shock absorbing function, Since the function can be maintained by the force generating member 31A, the reliability is improved. In particular, it is preferable when a tube is used as the repulsive force generating member 31A. The configuration of the present modification can also be applied to a repulsive force generating member that transmits power between the first annular body and the second annular body in the following examples.

(Second modification)
FIG. 3 is a meridional sectional view of a tire / wheel system according to a second modification of the first embodiment. In this modification, the tire / wheel system 10B includes a plurality of (two in this example) repulsion between the first annular body 11B and the second annular body 21B having the first member 11Ba and the second member 11Bb. Force generating members 31Ba and 31Bb are interposed. The repulsive force generating members 31Ba and 31Bb extend in the circumferential direction, similarly to the above-described repulsive force generating member 31 (see FIG. 1). In addition, like the repulsive force generating member 31A (see FIG. 2) described above, the repulsive force generating members 31Ba and 31Bb may extend in the circumferential direction and may be arranged in a plurality.

  The first annular body 11B has first convex portions 16Ba and 16Bb on both sides in the width direction. The first protrusions 16Ba and 16Bb protrude outward in the radial direction of the first annular body 11B. In the present modification, the first protrusions 16Ba and 16Bb have inclined surfaces 16SLa and 16SLb whose radius increases from the inner side in the width direction toward the outer side. The second annular body 21B has a rubber layer 22 on the outer peripheral portion and second convex portions 28Ba and 28Bb on both sides in the width direction. The second protrusions 28Ba and 28Bb protrude inward in the radial direction of the second annular body 21B. In the present modification, the second protrusions 28Ba and 28Bb have inclined surfaces 28SLa and 28SLb whose radius decreases from the inner side to the outer side in the width direction. The inclined surface 16SLa and the inclined surface 28SLa are substantially parallel, and the inclined surface 16SLb and the inclined surface 28SLb are substantially parallel.

  In this modification, the repulsive force generating members 31Ba and 31Bb are interposed between the first convex portion 16Ba and the second convex portion 28Ba, and between the first convex portion 16Bb and the second convex portion 28Bb, respectively. For this reason, the repulsive force generating member 31Ba is interposed between the inclined surface 16SLa and the inclined surface 28SLa, and the repulsive force generating member 31Bb is interposed between the inclined surface 16SLb and the inclined surface 28SLb. The repulsive force generating members 31Ba and 31Bb generate a repulsive force when compressed between the first annular body 11B and the second annular body 21B. The respective repulsive forces are transmitted to the inclined surface 16SLa and the inclined surface 28SLa, and the inclined surface 16SLb and the inclined surface 28SLb. The inclined surface 16SLa and the inclined surface 28SLa, and the inclined surface 16SLb and the inclined surface 28SLb generate a force component in the width direction and a component in the radial direction from the repulsive force. With such a structure, the tire / wheel system 10B can exhibit the function of the spring in the width direction (lateral spring) and the function of the spring in the radial direction (vertical spring) by the repulsive force generation members 31Ba and 31Bb.

  In this modification, the repulsive force generating members 31Ba and 31Bb both use tubes, and may be configured so that the pressure of the gas filled therein can be adjusted. With such a structure, the tire / wheel system 10B can simultaneously change the longitudinal rigidity and the lateral rigidity (stiffness in the width direction). The repulsive force generating members 31Ba and 31Bb may be solid members.

  As described above, in the present embodiment and its modification, a repulsive force generating member having a function as a vertical spring and a force transmitting function is interposed between the first annular body and the second annular body. With such a structure, it is possible to provide a tire / wheel assembly in which a solid rubber layer (not filled with gas) is a tread portion with a simple structure without using a complicated link mechanism or the like. Thus, this embodiment and its modification can provide a new tire / wheel system having a non-pneumatic tire. In this embodiment, if a tube capable of filling the internal space with gas and adjusting the pressure of the gas is used as the repulsive force generating member, the longitudinal rigidity of the tire / wheel system can be easily adjusted and changed. The configuration according to the present embodiment and its modifications can be applied as appropriate in the following.

(Embodiment 2)
FIG. 4 is a meridional sectional view showing the tire / wheel system according to the second embodiment. In the present embodiment, the repulsive force generating member interposed between the first annular body 11 and the second annular body 21C is formed between the outer peripheral portion 11I of the first annular body 11 and the inner peripheral portion 27 of the second annular body 21C. At least one first repulsive force generating member 31C interposed therebetween, and at least one second repulsive force generating member 32a, 32b interposed between the first convex portions 16a, 16b and the second convex portions 28a, 28b, And 32c. Configurations common to the first embodiment and its modification are given the same reference numerals.

  The first repulsive force generating member 31C corresponds to the repulsive force generating member 31 (FIG. 1) of the above-described embodiment, and is between the outer peripheral portion 11I of the first annular body 11 and the inner peripheral portion 27 of the second annular body 21C. Intervene. The first repulsive force generating member 31C is a member that generates a repulsive force against compression. The first repulsive force generating member 31C is arranged over the entire circumference in the circumferential direction of the tire / wheel system 10C. As shown in FIG. 4, the first repulsive force generating member 31 </ b> C is in contact with both the outer peripheral portion 11 </ b> I of the first annular body 11 and the inner peripheral portion 27 of the second annular body 21 </ b> C and is sandwiched between both. On the other hand, in the width direction, the first repulsive force generating member 31C does not contact either the first annular body 11 or the second annular body 21C.

  As described above, the first repulsive force generating member 31C functions as a vertical spring of the tire / wheel system 10C. In the present embodiment, the function of transmitting force between the first annular body 11 and the second annular body 21C is performed by the second repulsive force generating members 32a, 32b, and 32c, so the first repulsive force generating member 31C is The force may not be transmitted between the first annular body 11 and the second annular body 21C. Actually, since the first repulsive force generating member 31C is in contact with the first annular body 11 and the second annular body 21C, a certain amount of force is transmitted between them by the frictional force. In the tire / wheel system in which the transmission of force between the first annular body and the second annular body and the vertical spring function are separated, the above matters are the same.

  At least one first repulsive force generating member 31C is interposed between the first annular body 11 and the second annular body 21C. FIG. 4 shows an example in which one first repulsive force generating member 31C is interposed near the center in the width direction, but the arrangement example of the first repulsive force generating member 31C is not limited to this. For example, two or more first repulsive force generating members 31C may be arranged side by side with a predetermined interval in the width direction. The second annular body 21C is the same as the first embodiment in that the inner circumferential portion 27 has convex portions 37a and 37b for restricting movement of the first repulsive force generating member 31C in the width direction.

  In the present embodiment, the tire / wheel system 10C includes three second repulsive force generating members 32a, 32b, and 32c. The second repulsive force generating members 32a, 32b, and 32c are members that generate a repulsive force against compression. The second repulsive force generating member 32a is interposed between the first convex portion 16a and the second convex portion 28a. The second repulsive force generating members 32b and 32c are interposed between the first convex portion 16b and the second convex portion 28b. The second repulsive force generating members 32a, 32b, and 32c are arranged over the entire circumference in the circumferential direction of the tire / wheel system 10C. The second repulsive force generating members 32a, 32b, and 32c may not be continuous in the circumferential direction, and may be disposed intermittently.

  The second repulsive force generating member 32a interposed between the first convex portion 16a and the second convex portion 28a comes into contact with the surface 35 of the first convex portion 16a and the surface 36 of the second convex portion 28a, respectively. With such a structure, the second repulsive force generating member 32a is sandwiched between the first convex portion 16a and the second convex portion 28a. Since the second repulsive force generating member 32a has a predetermined gap between the first annular body 11 and the second annular body 21C in the radial direction, the second repulsive force generating member 32a is not sandwiched between the first annular body 11 and the second annular body 21C.

  The second repulsive force generating members 32b and 32c interposed between the first convex portion 16b and the second convex portion 28b are in contact with the surface 35 of the first convex portion 16b and the surface 36 of the second convex portion 28b, respectively. . With such a structure, the second repulsive force generating members 32b and 32c are sandwiched between the first convex portion 16b and the second convex portion 28b. Since the second repulsive force generating members 32a and 32b have a predetermined clearance from the first annular body 11 and the second annular body 21C in the radial direction, they are not sandwiched between the first annular body 11 and the second annular body 21C.

  In the present embodiment, the second repulsive force generating members 32a and 32b are solid members, and the second repulsive force generating member 32c is a tube. The second repulsive force generating members 32a, 32b, and 32c can be manufactured using the same material as the repulsive force generating member 31 and the first repulsive force generating member 31C of the first embodiment. As will be described later, the second repulsive force generating members 32a, 32b, and 32c transmit force by frictional force, and may be reinforced with fibers.

  The second repulsive force generating members 32a, 32b, and 32c function as a lateral spring of the tire / wheel system 10C. That is, the second repulsive force generating members 32a, 32b, and 32c absorb an impact in the width direction of the tire / wheel system 10C and support a load in the width direction (for example, a load during cornering). At the same time, the second repulsive force generating member 32a transmits a force between the first convex portion 16a and the second convex portion 28a by a frictional force generated between the first convex portion 16a and the second convex portion 28a. To do. Similarly, the second repulsive force generating members 32b and 32c are between the first convex portion 16b and the second convex portion 28b by the frictional force generated between the first convex portion 16b and the second convex portion 28b. Transmit power. The first convex portions 16a and 16b and the second convex portions 28a and 28b are respectively annular plate members. For this reason, since a contact area with the 2nd repulsive force generating member 32a, 32b, 32c can be ensured, force can be transmitted reliably.

  In the present embodiment, the tire / wheel system 10C includes three second repulsive force generating members 32a, 32b, and 32c, and the number and arrangement of the second repulsive force generating members are not limited to those described above. Further, the cross-sectional shapes (the cross-sectional shapes orthogonal to the central axis) of the second repulsive force generating members 32a, 32b, and 32c are not limited to the substantially circular shape and the substantially rectangular shape shown in FIG. It is preferable that the second repulsive force generating members 32a, 32b, and 32c have a shape suitable for transmitting a force by a frictional force. The second repulsive force generating members 32a, 32b, and 32c preferably have a spring constant required as a lateral spring of the tire / wheel system 10C in the compression direction. For example, the spring constant of the second repulsive force generating members 32a, 32b, and 32c is preferably 30 N / mm or more and 300 N / mm or less.

  The second repulsive force generating member 32c is a tube. Similarly to the repulsive force generating member 31 of the first embodiment, the second repulsive force generating member 32c applies a pressing force to the first convex portion 16b and the second convex portion 28b by filling the internal space with gas. . The second repulsive force generating member 32c can change the lateral rigidity of the tire / wheel system 10C by changing the pressure of the gas filled therein. The second repulsive force generating member 32 has a valve 41 for filling or discharging gas in the internal space. The valve 41 is inserted through a through hole 42 provided in the second member 11 b of the first annular body 11. With such a structure, the second repulsive force generating member 32c is a space surrounded by the first convex portion 16b, the second convex portion 28b, the first annular body 11 and the second annular body 21C as shown in FIG. The pressure of the gas filled in the second repulsive force generating member 32c can be adjusted via the valve 41 from the outside of the tire / wheel system 10C. As a result, maintenance / inspection, gas replenishment, and adjustment of the lateral rigidity of the tire / wheel system 10C are facilitated.

  As shown in FIG. 4, the end portions 43 and 45 on the radially outer side of the first convex portions 16a and 16b are radially outer than the end portions 44 and 46 on the radially inner side of the second convex portions 28a and 28b. It is preferable. With such a structure, the first protrusions 16a, 16b and the second protrusions 28a, 28b can securely hold the second repulsive force generating members 32a, 32b, 32c. In addition, when a force in the width direction is applied to the tire / wheel system 10C, it is possible to avoid a situation in which the second annular body 21C is dropped from the first annular body 11.

  When the relative displacement in the radial direction between the second annular body 21C and the first annular body 11 occurs in the tire / wheel system 10C, the first repulsive force generating member 31C can receive the displacement. In the tire / wheel system 10C, when a relative displacement in the width direction between the second annular body 21C and the first annular body 11 occurs, the second repulsive force generating members 32a, 32b, and 32c receive the displacement. be able to. With such a structure, the first repulsive force generating member 31C has a vertical spring function of the tire / wheel system 10C, and the second repulsive force generating members 32a, 32b, and 32c have a horizontal spring function.

  The first repulsive force generating member 31C and at least one second repulsive force generating member are tubes, and the pressure of the gas filled in the internal space of the tube can be individually adjusted. According to such a structure, the longitudinal rigidity and the lateral rigidity of the tire / wheel system 10C can be adjusted separately. The longitudinal rigidity of the tire / wheel system 10C affects the ride comfort, and the lateral rigidity affects the steering stability and running stability of the vehicle. For this reason, the longitudinal stiffness and lateral stiffness of the tire / wheel system 10C are individually adjusted according to the running conditions to give priority to running performance, ride quality, and balance between running performance and ride quality. You can take it. Moreover, in this embodiment, as shown in FIG. 4, the 2nd repulsive force generating member 32c of a tube and the 2nd repulsive force generating members 32a and 32b which are solid members are combined. If it does in this way, lateral rigidity can be adjusted in a wider range.

  As described above, in the present embodiment, as the first repulsive force generating member that is interposed between the first annular body and the second annular body and that exhibits the function of the longitudinal spring, and between the first annular body and the second annular body. As at least one of the second repulsive force generating members that are interposed between them and exhibit the functions of a lateral spring and force transmission, a tube that can hold a gas inside and adjust its pressure is used. That is, in this embodiment, the function of the vertical spring and the function of the horizontal spring of the tire / wheel system are separated. With such a structure, the longitudinal stiffness and lateral stiffness of the tire / wheel system can be adjusted separately. In addition, by designing the first annular body and the second annular body separately, it becomes easy to design the longitudinal spring and the lateral spring separately and to give each of them appropriate performance. Furthermore, the tire / wheel system according to the present embodiment can prevent the first annular body from having a power transmission function. In this case, since the tube as the repulsive force generating member 31 can be specialized in the spring characteristics and the performance of gas leakage, the design of the first annular body becomes relatively easy. The configuration according to the present embodiment can also be applied as appropriate in the following.

(Embodiment 3)
FIG. 5 is a meridional sectional view showing the tire / wheel system according to the third embodiment. In the present embodiment, the repulsive force generating member interposed between the first annular body 11 and the second annular body 21D is at least interposed between the first convex portions 16a and 16b and the second convex portions 28Da and 28Db. It is characterized in that it is one second repulsive force generating member 32Da, 32Db. Configurations common to the first embodiment, the modification thereof, and the second embodiment are denoted by the same reference numerals.

  In the present embodiment, the tire / wheel system 10D includes two second repulsive force generating members 32Da and 32Db. These are members that generate a repulsive force against compression. The second repulsive force generating member 32Da is interposed between the first convex portion 16a and the second convex portion 28Da of the second annular body 21D. The second repulsive force generating member 32Db is interposed between the first convex portion 16b and the second convex portion 28Db of the second annular body 21D. The second repulsive force generating members 32a and 32b are arranged over the entire circumference in the circumferential direction of the tire / wheel system 10D. The second repulsive force generating members 32a and 32b may not be continuous in the circumferential direction, and may be disposed intermittently.

  The second repulsive force generating member 32a interposed between the first convex portion 16a and the second convex portion 28Da is in contact with the surface 35 of the first convex portion 16a and the surface 36 of the second convex portion 28Da, respectively. Further, the second repulsive force generating member 32a is in contact with the convex inner peripheral surface 28Dc of the second annular body 21D and the outer peripheral part 11I of the first annular body 11, respectively. As a result, the second repulsive force generating member 32a is sandwiched between the first convex portion 16a, the second convex portion 28Da, the first annular body 11 and the second annular body 21D.

  The second repulsive force generating member 32b interposed between the first convex portion 16b and the second convex portion 28Db is in contact with the surface 35 of the first convex portion 16b and the surface 36 of the second convex portion 28Db, respectively. Further, the second repulsive force generating member 32b comes into contact with the convex inner peripheral surface 28Dd of the second annular body 21D and the outer peripheral part 11I of the first annular body 11, respectively. As a result, the second repulsive force generating member 32b is sandwiched between the first convex portion 16b, the second convex portion 28Db, the first annular body 11 and the second annular body 21D.

  Due to the above structure, the second repulsive force generating member 32a has the first annular body due to the frictional force generated between the first convex portion 16a, the second convex portion 28Da, the first annular body 11 and the second annular body 21D. The force is transmitted between 11 and the second annular body 21D. Similarly, the second repulsive force generating member 32b has the first annular body 11 due to the frictional force generated between the first convex portion 16b, the second convex portion 28Db, the first annular body 11 and the second annular body 21D. The force is transmitted between the second annular body 21D and the second annular body 21D. Further, since the second repulsive force generating members 32a and 32b are interposed between the first annular body 11 and the second annular body 21D, respectively, the load in the radial direction of the tire / wheel system 10D is supported or an impact is applied. Or absorb. As described above, the second repulsive force generating members 32a and 32b function as a vertical spring of the tire / wheel system 10D. Further, since the second repulsive force generating members 32a and 32b are interposed between the first convex portion 16a and the second convex portion 28Da and between the first convex portion 16b and the second convex portion 28Db, respectively, It supports the load in the width direction of the wheel system 10D and absorbs an impact. As described above, the second repulsive force generating members 32a and 32b also function as a lateral spring of the tire / wheel system 10D.

  In the present embodiment, the second repulsive force generating members 32a and 32b are both tubes. The second repulsive force generating members 32a, 32b, and 32c can be manufactured using the same material as the repulsive force generating member 31 and the first repulsive force generating member 31C of the first embodiment. The second repulsive force generating members 32a and 32b transmit a force by a frictional force and also function as a vertical spring and a horizontal spring of the tire / wheel system 10D. For this reason, it may be reinforced with fibers. In the present embodiment, since the tire / wheel system 10D includes the second repulsive force generating members 32a and 32b of the tube, the longitudinal rigidity of the tire / wheel system 10D is adjusted by adjusting the pressure of the gas filled in the internal space. And the lateral stiffness can be changed simultaneously.

  In the present embodiment, the two second repulsive force generating members 32a and 32b have a force transmission function between the first annular body 11 and the second annular body 21D, and the vertical spring and lateral force of the tire / wheel system 10D. It takes on the function as a spring. For this reason, the number of repulsive force generating members of the tire / wheel system 10D can be reduced as compared with the second embodiment.

(Embodiment 4)
FIG. 6 is a meridional sectional view showing the tire / wheel system according to the fourth embodiment. The tire / wheel system 10E of the fourth embodiment is the same as the tire / wheel system 10C (see FIG. 4) of the second embodiment, but the types and number of the first repulsive force generating members and the second repulsive force generating members are as follows. The difference from Embodiment 2 is different. Other configurations are the same as those of the second embodiment.

  As shown in FIG. 6, the tire / wheel system 10E includes two first repulsive force generating members 31Ea and 31Eb. The first repulsive force generating members 31Ea and 31Eb are arranged side by side with a predetermined interval in the width direction. The first repulsive force generating member 31Ea is a tube. The first repulsive force generating member 31Ea has the same structure as when the repulsive force generating member 31 of Embodiment 1 is a tube. The first repulsive force generating member 31Ea is in contact with the outer peripheral portion 11I of the first annular body 11E having the first member 11Ea and the second member 11Eb and the inner peripheral portion 27 of the second annular body 21E. With such a structure, the first repulsive force generating member 31Ea is sandwiched between the first annular body 11E and the second annular body 21E. On the other hand, the first repulsive force generating member 31Ea is disposed so as not to contact the first annular body 11E and the second annular body 21E in the width direction. Further, the movement of the first repulsive force generating member 31Ea in the width direction is restricted by the convex portions 37a and 37b of the inner peripheral portion 27 of the second annular body 21E.

  The first repulsive force generating member 31Eb is a solid member. The first repulsive force generating member 31Eb is manufactured from the same material as the material of the repulsive force generating member 31 of the first embodiment. The first repulsive force generating member 31Eb extends in the circumferential direction of the first annular body 11E and goes around the first annular body 11E. As shown in FIG. 6, the cross-sectional shape of the first repulsive force generating member 31Ea (the cross-sectional shape orthogonal to the central axis) and the external cross-sectional shape of the first repulsive force generating member 31Eb (the external shape of the cross-section orthogonal to the central axis) Is round. In the present embodiment, the outer diameter of the first repulsive force generating member 31Eb is smaller than the outer diameter of the first repulsive force generating member 31Ea. For this reason, the first repulsive force generating member 31Eb contacts only with the outer peripheral portion 11I of the first annular body 11E, and has a predetermined distance d in the radial direction between the inner peripheral portion 27 of the second annular body 21E. ing. Further, the first repulsive force generating member 31Eb is disposed so as not to contact either the first annular body 11E or the second annular body 21E in the width direction, like the first repulsive force generating member 31Ea. Further, the movement of the first repulsive force generating member 31Eb in the width direction is restricted by the convex portions 37c and 37d included in the outer peripheral portion 11I of the first annular body 11E.

  The first repulsive force generating members 31Ea and 31Eb function as vertical springs of the tire / wheel system 10E, as in the first embodiment. The function of this vertical spring will be described. Since the first repulsive force generating member 31Ea is sandwiched between the first annular body 11E and the second annular body 21E, the first repulsive force generating member 31C is first deformed by the radial input. When the relative displacement in the radial direction between the first annular body 11E and the second annular body 21E reaches the predetermined distance d, the second annular body 21E contacts the first repulsive force generating member 31Eb. Then, the spring constant in the radial direction of the tire / wheel system 10E is the sum of the spring constant of the first repulsive force generating member 31Ea and the spring constant of the first repulsive force generating member 31Eb. As a result, the longitudinal rigidity of the tire / wheel system 10E changes depending on the magnitude of the displacement. Specifically, the tire / wheel system 10E has a relatively small longitudinal stiffness when the displacement is small, but the longitudinal stiffness increases rapidly when the displacement exceeds a certain value. As a result, in the tire / wheel system 10E, the radial deformation of the tire / wheel system 10E with respect to a large displacement in the radial direction is suppressed, so that a decrease in steering stability is suppressed. On the other hand, the tire / wheel system 10E is easily deformed in the radial direction with respect to the radial input of a small displacement, so that the riding comfort is improved.

  In the present embodiment, the second repulsive force generating members 32a and 32d are interposed between the first convex portion 16a and the second convex portion 28Da and between the first convex portion 16b and the second convex portion 28Db, respectively. The second repulsive force generating member 32a transmits a force between the first annular body 11E and the second annular body 21E by a frictional force generated between the first convex portion 16a and the second convex portion 28Da. The second repulsive force generating member 32d is a member that generates a repulsive force against compression, and the first annular body 11E is caused by the frictional force generated between the first convex portion 16b and the second convex portion 28Db. A force is transmitted to and from the second annular body 21E. Thus, in this embodiment, since the 2nd repulsive force generating members 32a and 32b transmit force between the 1st annular body 11 and the 2nd annular body 21C, the 1st repulsive force generating members 31Ea and 31Eb are The force may not be transmitted between the first annular body 11E and the second annular body 21E.

  Further, the second repulsive force generating members 32a and 32b also function as a lateral spring of the tire / wheel system 10E. In the present embodiment, the second repulsive force generating member 32a is a solid member, and the second repulsive force generating member 32b is a tube. The lateral rigidity of the tire / wheel system 10E can be changed by adjusting the pressure of the gas filled in the internal space of the tube as the second repulsive force generating member 32b. Further, by adjusting the pressure of the gas, the second repulsive force generating member 32a, the first convex portion 16a, and the second convex portion 28Da, the second repulsive force generating member 32b, the first convex portion 16b, and the first convex portion 16b. The magnitude of the frictional force generated between the two convex portions 28Db can be changed.

  As described above, the tire / wheel system according to the present invention is useful for a non-pneumatic tire having a solid tread portion.

10, 10A, 10B, 10C, 10D, 10E Tire / wheel system 11, 11A, 11B, 11E First annular body 11I Outer peripheral part 11Sa, 11Sb Groove 11a, 11Ba, 11Ea First member 11b, 11Bb, 11Eb Second member 12 Spoke 13 Hub 14 First engaging portion 16SLa, 16SLb, 28SLa, 28SLb Inclined surface 16a, 16b, 16Ba, 16Bb First convex portion 16Ba Convex portion 16Bb Convex portion 19 Bolt 21, 21A, 21B, 21C, 21D Second annular body 22 Rubber layer 23 Outer peripheral portion 27 Inner peripheral portion 28a, 28b, 28Ba, 28Bb, 28Da, 28Db Second convex portion 28Dc, 28Dd Convex inner peripheral surface 29 Heat radiation holes 31, 31A, 31Ba, 31Bb Repulsive force generating members 31C, 31Ea, 31Eb first repulsive force generating member 3 1I Internal space 32a, 32b, 32c, 32d, 32Da, 32Db Second repulsive force generating member 38, 41 Valve 39, 42 Through hole 47a, 47b Stopper 50 Engagement part

Claims (7)

A first annular body that is a cylindrical member;
A cylindrical member disposed radially outward of the first annular body, and a second annular body having a rubber layer on the outer periphery;
It is interposed between the first annular body and the second annular body, extends in the circumferential direction of the first annular body and the second annular body, and generates a repulsive force against compression. A repulsive force generating member;
A first protrusion projecting radially outward from the outer periphery of the first annular body;
Both project in the direction parallel to the central axis of the first annular body and the second annular body by projecting radially inward from the inner peripheral portion of the second annular body and engaging with the first convex portion. A second convex portion for restricting relative movement of
Only including,
The repulsive force generating member is
At least one first repulsive force generating member interposed between an outer peripheral portion of the first annular body and an inner peripheral portion of the second annular body;
Having at least one second repulsive force generating member interposed between the first convex portion and the second convex portion,
The first repulsive force generating member is a tube extending in the circumferential direction and a solid member extending in the circumferential direction, and the dimension in the radial direction of the first annular body is the tube. Tire / wheel system, characterized in that is larger . The tire / wheel system according to claim 1 , wherein the first annular body is divided into two or more in a direction parallel to the central axis. The tire / wheel system according to claim 1 or 2 , wherein each of the first protrusion and the second protrusion is an annular plate member. The first annular body has two or more first convex portions in a direction parallel to the central axis,
The tire / wheel system according to claim 3 , wherein the second annular body has two or more second convex portions in a direction parallel to the central axis. 5. The tire / wheel system according to claim 4 , wherein an end portion on the radially outer side of the first convex portion is radially outer side than an end portion on the radially inner side of the second convex portion. At least one of the first repulsive force generating members is a tube extending in the circumferential direction,
The tire / wheel system according to any one of claims 1 to 5 , further comprising a valve for filling a gas into the tube. At least one of the second repulsive force generating members is a tube extending in the circumferential direction,
The tire / wheel system according to any one of claims 1 to 5 , further comprising a valve for filling a gas into the tube.

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