FIELD OF INVENTION

[0001] The present disclosure relates to a non-pneumatic tire. More particularly, the present disclosure relates to a non-pneumatic tire having a support structure with spokes that are designed to contact one another during the occurrence of a high impact event.

BACKGROUND

[0002] Various tire constructions have been developed that enable a tire to run in an uninflated or underinflated condition. Non-pneumatic tires do not require inflation, while “run flat tires” may continue to operate after being punctured and becoming partially or completely depressurized, for extended periods of time and at relatively high speeds. Non-pneumatic tires may include support structure, such as spokes or webbing, that connects a lower ring to an upper ring. In some non- pneumatic tires, a circumferential tread may be attached to the upper ring of the tire.

[0003] The circumferential tread may contain a tread band. The tread band may be a single layer of material or a multi-layer band. Such tread bands may also be referred to as a shear band, a shear element, or a thin annular high strength band element. When used in a non-pneumatic tire, or in a pneumatic tire in a partially pressurized or unpressurized state, the shear element acts as a structural compression member. When used in a fully pressurized pneumatic tire, the shear element acts as a tension member.

[0004] Tire design, for both pneumatic and non-pneumatic tires, involves the balancing of many factors including, but not limited to, load capacity, handling, and ride quality. Regardless of the balance that is selected between these factors, non- pneumatic tires must be durable and be able to withstand high impact events, such as hitting a curb, pothole, or other obstruction or road imperfection.

SUMMARY OF THE INVENTION

[0005] In one embodiment, a non-pneumatic tire includes a lower ring having a first diameter and an upper ring having a second diameter. The upper ring is substantially coaxial with the lower ring. A support structure connects the lower ring to the upper ring. The support structure is made up of a plurality of spokes. The plurality of spokes are arranged into a first spoke group and a second spoke group that is axially spaced from the first spoke group. Each one of the plurality of spokes includes a first end connected to the lower ring, a second end connected to the upper ring, and a boot at the first end. The boot has a floor portion. The floor portion is attached to the lower ring to connect the first end of the spoke to the lower ring.

[0006] In another embodiment, a method of manufacturing a non-pneumatic tire includes providing a lower ring having a first diameter and an upper ring having a second diameter that is greater than the first diameter. A plurality of scallops are formed on the lower ring. Each one of the plurality of scallops has a first curved surface. A plurality of spokes are formed. Each spoke extends between a first end and a second end. A plurality of boots are formed. Each one of the plurality of boots has a second curved surface. The plurality of boots are attached to a respective one of the plurality of spokes at the first end. The plurality of spokes are arranged into a first spoke group and a second spoke group that is axially spaced from the first spoke group. The method further includes connecting the lower ring to the upper ring with the first spoke group and the second spoke group. The step of connecting the lower ring to the upper ring includes attaching the second curved surface of the boot to the first curved surface of one of the plurality of scallops to connect the first end of the spoke to the lower ring, and connecting the second end of the spoke to the upper ring.

[0007] In yet another embodiment, a non-pneumatic tire includes a lower ring having a first radius of curvature. The lower ring is provided with a plurality of scallops. Each scallop has a first curved surface with a second radius of curvature. An upper ring is coaxial with the lower ring. A support structure connects the lower ring to the upper ring. The support structure is made up of a plurality of spokes. Each spoke extends between a first end and a second end. The first end is provided with a boot. The boot has a third radius of curvature. Each of the first radius of curvature and the second radius of curvature are different from the third radius of curvature.

BRIEF DESCRIPTION OF DRAWINGS

[0008] In the accompanying drawings, structures are illustrated that, together with the detailed description provided below, describe exemplary embodiments of the claimed invention. Like elements are identified with the same reference numerals. It should be understood that elements shown as a single component may be replaced with multiple components, and elements shown as multiple components may be replaced with a single component. The drawings are not to scale and the proportion of certain elements may be exaggerated for the purpose of illustration.

[0009] Figure l is a side view of one embodiment of a non-pneumatic tire, [0010] Figure 2 is another side view of the non-pneumatic tire of Figure 1,

[0011] Figure 3 is a sectional view along 3-3 of Figure 1,

[0012] Figure 4 is a detail view of Area A of Figure 1,

[0013] Figure 5 is a detail view of Area A of Figure 1 with some features removed for clarity,

[0014] Figure 6 is a detail view of a single spoke that is used in the non- pneumatic tire of Figure 1,

[0015] Figure 7 is a side view of part of the non-pneumatic tire of Figure 1 when the tire is on a flat surface and carrying a normal load,

[0016] Figure 8 is a side view of part of the non-pneumatic tire of Figure 1 when the tire is on a flat surface and carrying a normal load, with some features removed for clarity,

[0017] Figure 9 is a side view of part of the non-pneumatic tire of Figure 1 when the tire is on an uneven surface, [0018] Figure 10 is a side view of part of the non-pneumatic tire of Figure 1 when the tire is on an uneven surface, with some features removed for clarity, [0019] Figure 11 is a flow chart showing a method of manufacturing the nonpneumatic tire of Figure 1,

[0020] Figure 12 is another embodiment of a spoke for a non-pneumatic tire, [0021] Figure 12a is an end view of the spoke of Figure 12 along I-I,

[0022] Figure 13 is a side view of a non-pneumatic tire showing the effect of manufacturing tolerances in spokes before a second end of the spokes are attached to an upper ring,

[0023] Figure 14 is a side view of the non-pneumatic tire of Figure 13 after the second end of the spokes are attached to the upper ring,

[0024] Figure 15 is a partial view of another embodiment of a non-pneumatic tire,

[0025] Figure 16 is a detail view of a single spoke that is used in the non- pneumatic tire of Figure 15.

[0026] Figure 17 is a view along 17-17 of Figure 15,

[0027] Figure 18 is a partial view of another embodiment of a non-pneumatic tire,

[0028] Figure 19 is a perspective view of an end cap,

[0029] Figure 20 is a partial side view of another embodiment of a non- pneumatic tire,

[0030] Figure 21 is a partial perspective view of the non-pneumatic tire of

Figure 20, and

[0031] Figure 22 is another partial perspective view of the non-pneumatic tire of Figure 20.

DETAILED DESCRIPTION

[0032] The following includes definitions of selected terms employed herein. The definitions include various examples or forms of components that fall within the scope of a term and that may be used for implementation. The examples are not intended to be limiting. Both singular and plural forms of terms may be within the definitions.

[0033] “Axial” and “axially” refer to a direction that is parallel to the axis of rotation of a tire.

[0034] Circumferential” and “circumferentially” refer to a direction extending along the perimeter of the surface of the tread perpendicular to the axial direction.

[0035] “Radial” and “radially” refer to a direction perpendicular to the axis of rotation of a tire.

[0036] Tread” as used herein, refers to that portion of the tire that comes into contact with the road or ground under normal inflation and normal load.

[0037] While similar terms used in the following descriptions describe common tire components, it should be understood that because the terms carry slightly different connotations, one of ordinary skill in the art would not consider any one of the following terms to be purely interchangeable with another term used to describe a common tire component.

[0038] Directions are stated herein with reference to the axis of rotation of the tire. The terms “upward” and “upwardly” refer to a general direction towards the tread of the tire, whereas “downward” and “downwardly” refer to the general direction towards the axis of rotation of the tire. Thus, when relative directional terms such as “upper” and “lower” or “top” and “bottom” are used in connection with an element, the “upper” or “top” element is spaced closer to the tread than the “lower” or “bottom” element. Additionally, when relative directional terms such as “above” or “below” are used in connection with an element, an element that is “above” another element is closer to the tread than the other element.

[0039] The terms “inward” and “inwardly” refer to a general direction towards the equatorial plane of the tire, whereas “outward” and “outwardly” refer to a general direction away from the equatorial plane of the tire and towards the side of the tire. Thus, when relative directional terms such as “inner” and “outer” are used in connection with an element, the “inner” element is spaced closer to the equatorial plane of the tire than the “outer” element. [0040] Figures 1-5 illustrate one embodiment of a non-pneumatic tire 10. The non-pneumatic tire 10 is merely an exemplary illustration and is not intended to be limiting. In the illustrated embodiment, the non-pneumatic tire 10 includes a generally annular lower ring 20. The lower ring 20 may engage a vehicle hub (not shown) for attaching the tire 10 to a vehicle. The lower ring 20 has an internal surface 23 and an external surface 24, and may be made of a polymeric material, an elastomeric material, a metal, a composite made up of polymers reinforced with glass or carbon fibers, or any other desired material or combination of materials.

[0041] The non-pneumatic tire 10 further includes a generally annular upper ring 30. The upper ring 30 has a diameter that is greater than a diameter of the lower ring 20, and is substantially coaxial with the lower ring 20. The upper ring 30 has an internal surface 33 and an external surface 34, and may be made out of a polymeric material, an elastomeric material, a metal, a composite made up of polymers reinforced with glass or carbon fibers, or any other desired material or combination of materials. A circumferential tread 70 is attached to the external surface 34 of the upper ring 30. The circumferential tread 70 may be attached to the upper ring 30 adhesively, mechanically, or by any other desired arrangement.

[0042] As shown in Figure 3, the circumferential tread 70 includes a tread band 72 and a tread layer 74. The tread band 72 and the tread layer 74 may be made of out of the same material or different material. The tread layer 74 may be made out of rubber, and may include tread elements (not shown) such as grooves, ribs, blocks, lugs, sipes, studs, or any other desired tread elements. The tread band may include a filament assembly.

[0043] In the illustrated embodiment, the tread band 72 is shown as a single layer. In alternative embodiments, the tread band may be a multi-layer band. Such multi-layer tread bands may include one or more layers of substantially inextensible material. The layers may be formed of sheets of material, cords of material, filaments of material, or any other desired arrangement. In other alternative embodiments, the multi-layer tread band may include a layer of extensible material, such as an elastomer. According to one example embodiment, the tread band may include a pair of inextensible layers separated by a layer of extensible material. In still other alternative embodiments, the tread band may include bands that are referred to as shear bands, shear elements, or thin annular high strength band elements.

[0044] Support structure 100 connects the lower ring 20 to the upper ring 30. The support structure 100 extends from the external surface 24 of the lower ring 20 and the internal surface 33 of the upper ring 30. The support structure 100 is made up of a plurality of spokes 200. In the illustrated embodiment, the plurality of spokes 200 are arranged into two axially spaced spoke groups, including a first spoke group 202 and a second spoke group 204 axially spaced from the first spoke group 202. In alternative embodiments, the support structure may include more than two axially spaced spoke groups.

[0045] As shown in Figure 3, the first spoke group 202 and the second spoke group 204 spaced apart from one another in the axial direction. In alternative embodiments, the space between the first spoke group and the second spoke group may be larger or smaller, or the first and second spoke groups may be arranged with no space therebetween. When viewed from the perspective shown in Figure 1, each spoke 200 of the first spoke group 202 is substantially convex relative to a clockwise circumferential direction of the non-pneumatic tire 10, and each spoke of the second spoke group 204 is substantially concave relative to the clockwise circumferential direction of the non-pneumatic tire 10.

[0046] All of the spokes 200 of the first and second spoke groups 202, 204 have the same configuration. Accordingly, the description of the spokes 200 will be made with reference to the single spoke 200 shown in Figure 6. The spoke 200 may be manufactured out of metals such as steel or aluminum, polymers such as polyester or nylon, composites such as fiberglass or carbon fiber reinforced polymers, or any other desired material or combination of materials. The spoke 200 may be provided with reinforcements (not shown).

[0047] The spoke 200 extends between a first end 206 and a second end 208, and has a substantially rectangular cross section that includes a first surface 210 and a second surface 212 facing opposite the first surface 210. A spoke thickness t refers to the distance between the first and second surfaces 210, 212. In the illustrated embodiment, the spoke 200 has a constant thickness between the first end 206 and the second end 208. In alternative embodiments, the thickness of the spoke may vary between the first and second ends. For example, the spoke may have relatively thicker portions at the first and second ends and a relatively thinner portion between the ends. In other alternative embodiments, the spoke may have any desired cross section shape (e.g., circle, diamond, hexagon, etc.) or may have a combination of different cross section shapes.

[0048] An integral foot portion 214 is provided toward the first end 206 of the spoke 200. The first surface 210 of the spoke 200 at the foot portion 214 is attached to the external surface 24 of the lower ring 20 to connect the first end 206 of the spoke 200 to the lower ring 20. The foot portion 214 may be attached to the external surface 24 of the lower ring 20 using welding, brazing, soldering, adhesives, mechanical fasteners (e.g., bolts, rivets), key/keyway, or any other desired arrangement. In the illustrated embodiment, the foot portion 214 is substantially straight, and the entire length (dimension of the foot portion extending along the circumferential direction of the tire) and the entire width (dimension of the foot portion extending along the axial direction of the tire) is secured to the external surface 24 of the lower ring 20. In alternative embodiments, the foot portion may be a separate component that is attached to the spoke. In other alternative embodiments, the foot portion may be curved to match the radius of curvature of the external surface of the lower ring or have any other desired curvature. In still other alternative embodiments, only a part or multiple discrete parts of the foot portion may be attached to the external surface of the lower ring. In still yet other alternative embodiments, the foot portion may be attached below the external surface of the lower ring, or the spoke may extend through the lower ring so that the foot portion can be attached to the internal surface of the lower ring.

[0049] A flexure member 216 is provided at the second end 208 of the spoke 200. The flexure member 216 has a width that extends along the axial direction of the tire. The flexure member 216 may be manufactured out of a polymer (e.g., urethane or rubber), a thin, curved piece of metal, or any other desired material or combination of materials. In the illustrated embodiment, the flexure member 216 is provided as a rectangular cuboid and arranged so that an end of the flexure member 216 is aligned with the second end 208 of the spoke 200. In other alternative embodiments, the flexure member may be arranged so that an end of the flexure member is set back from the second end of the spoke, or may be arranged so that an end of the flexure member extends beyond the second end of the spoke. In still yet other alternative embodiments, the flexure member may be replaced with a mechanical pinned joint (z.e., hinge).

[0050] The flexure member 216 includes a spoke facing surface 218 and a ring facing surface 220. The spoke facing 218 surface of the flexure member 216 is attached to the second surface 212 of the spoke 200 and the ring facing surface 220 is attached to the internal surface 33 of the upper ring 30 to connect the second end 208 of the spoke 200 to the upper ring 30. The attachment between the flexure member 216 and the spoke 200 or between the flexure member 216 and the upper ring 30 may be achieved using welding, brazing, soldering, adhesives, mechanical fasteners (e.g., bolts, rivets), key/keyway, or any other desired arrangement. For example, the attachment may be provided by casting urethane directly against the spoke, with or without the spoke being first coated in a primer.

[0051] The flexure member 216 provides flexibility to the connection between the second end 208 of the spoke 200 and the upper ring 30. This flexibility decreases the chances of high stresses being generated within the spoke 200, thereby improving the robustness of the non-pneumatic tire 10. In comparison to the flexible connection provided by the flexure member 216, the connection provided by the foot portion 214 at the first end 206 of the spoke 200 is more rigid. [0052] In alternative embodiments, the flexure member may have a shape or configuration that is different from what is specifically shown and described. In other alternative embodiments, additional structure(s) or mechanism(s) may supplement the flexure member to attach the second end of the spoke to the upper ring. In still other alternative embodiments, the flexure member may be omitted and the second end of the spoke may be directly attached to the upper ring. In these alternative embodiments, the second end of the spoke may be attached directly to the internal surface of the upper ring, above the internal surface of the upper ring, or the spoke may extend through the upper ring so that the second end can be attached to the external surface of the upper ring.

[0053] The spoke 200 includes a knee portion 222 between the first end 206 and the second end 208. The knee portion 222 has a first radius of curvature n. According to one example embodiment, the first radius of curvature ri is 2-6 inches (5-15 cm). When attached to the upper and lower rings 20, 30, the knee portion 222 is concavely curved relative to the lower ring 20.

[0054] A transition portion 224 is provided between the knee portion 222 and the first end 206. The transition portion 224 has a second radius of curvature r2. According to one example embodiment, the second radius of curvature r2 is 0-2 inches (0-5 cm). When attached to the upper and lower rings 20, 30, the transition portion 224 is convexly curved relative to the lower ring 20. Thus, relative to a single spoke 200, the knee portion 222 and the transition portion 224 are concavely curved in opposite facing directions. In alternative embodiments, the knee portion and the transition portion are concavely (or convexly) curved in the same direction. [0055] The foot portion 214 extends from the transition portion 224 to the first end 206 of the spoke 200. A first connecting portion 226 connects the transition portion 224 to the knee portion 222, and a second connecting portion 228 connects the knee portion 222 to the second end 208 of the spoke 200. In the illustrated embodiment, the first and second connecting portions 226, 228 are both linear. In alternative embodiments, the first connecting portion or the second connecting portion may be curved or have any other desired configuration. In other alternative embodiments, the transition portion and the foot portion may be omitted. In such alternative embodiments, the first end of the spoke would be located at the end of the first connecting portion.

[0056] A base plane pi intersects the transition portion 224 and the second end 208 of the spoke 200, and serves as a reference for various dimensional aspects of the spoke 200. The angle between the base plane pi and a second plane p2 extending tangentially to the external surface 24 of the lower ring 20 at the transition portion 224 is a. According to one example embodiment, the angle «is 5-20 degrees. The distance between the transition portion 224 and the second end 208 of the spoke 200 along a direction parallel to the base plane pi is di. According to one example embodiment, the distance di is 10-15 inches (25-38 cm). The distance between a center of the transition portion 224 and the center of the first radius of curvature ri of the knee portion 222 along a direction parallel to the base plane pi is tfe. According to one example embodiment, the value of the distance is 40-70 percent of the distance di. The maximum distance between the knee portion 222 and the base plane pi along a direction perpendicular to the base plane pi is ds. According to one example embodiment, the distance r/j is 2-4 inches (5-10 cm).

[0057] Referring to Figure 10, the transition portion 224 of one spoke 200 is separated from the first end 206 of an adjacent spoke 200 by a first spacing distance si. The second end 208 of adjacent spokes 200 are separated from one another by a second spacing distance S2.

[0058] A non-pneumatic tire constructed in accordance with the above described design parameters may provide a more robust assembly, especially in terms of impact performance. Figures 7 and 8 shows the tire in an exemplary first condition. As shown Figures 7 and 8, according to a non-limiting example, in the first condition the tire 10 is rolling on a flat surface while carrying a load (z.e., normal operation), the non-pneumatic tire 10 deforms, but adjacent spokes 200 are not in contact with one another. The lack of contact between adjacent spokes 200 during normal operation is desirable to avoid the creation of unnecessary stresses in the structure of the non-pneumatic tire 10.

[0059] It is expected that the non-pneumatic tire 10 will be exposed to a high impact event during its lifetime, such as hitting a curb, pothole, or other obstruction or road imperfection. During a high impact event, the non-pneumatic tire 10 may deform at significantly higher levels than the deformation that occurs during normal operation.

[0060] Figures 9 and 10 show the tire in an exemplary second condition, the second condition being different from the first condition. As shown in Figures 9 and 10, according to a non-limiting example, in the second condition the non- pneumatic tire 10 experiences a high impact event, in which the tire rolls over an uneven surface. According to one non-limiting example, the uneven surface is a road imperfection that protrudes above the ground, or depresses into the ground, a distance of 3 inches (8 cm). According to another non-limiting example, the uneven surface is a road imperfection that protrudes above the ground, or depresses into the ground, a distance of 4.5 inches (11 cm). According to yet another non-limiting example, the uneven surface is a road imperfection that protrudes above the ground, or depresses into the ground, a distance of 6 inches (15 cm).

[0061] The non-pneumatic tire 10 responds to the high impact event by deforming so that adjacent spokes 200 contact one another. It has been found that, surprisingly, the contact between adjacent spokes 200 during a high impact event significantly lowers the stress experienced by an individual spoke 200 compared to a non-pneumatic tire where spokes do not contact one another during a high impact event. The reduction of stress in an individual spoke 200 is a result of the contact between the adjacent spokes 200, as the contact distributes the load among multiple spokes 200. In other words, rather than a single spoke 200 absorbing the load arising from the high impact event, multiple spokes 200 share the same load, thus reducing the peak load of any one single spoke 200.

[0062] In the illustrated embodiment, the non-pneumatic tire 10 is arranged and configured so that at least three adjacent spokes 200 are in simultaneous contact with one another during a high impact event, and the spokes 200 in contact with one another are located adjacent to the obstruction or road imperfection responsible for the high impact event. In alternative embodiments, the non-pneumatic tire may be arranged and configured to have a fewer or greater number of adjacent spokes in simultaneous contact with one another during a high impact event. In other alternative embodiments, the adjacent spokes in simultaneous contact with one another may be located at any location along the circumferential direction of the tire (ie., spaced away from the obstruction or road imperfection responsible for the high impact event).

[0063] Design parameters of the spokes 200 and other components of the non- pneumatic tire 10 may be altered to provide the non-pneumatic tire 10 with desired performance characteristics. Preferably, these design parameters are selected so that contact between adjacent spokes 200 occurs before the spoke 200 begins to yield or experience any other forms of damage.

[0064] The maximum distance ds between the knee portion 222 and the base plane pi along a direction perpendicular to the base plane pi, affects spoke stiffness and when contact between adjacent spokes 200 will occur. Increasing the distance ds will physically move each spoke 200 closer to adjacent spokes 200, thus causing contact between adjacent spokes 200 to occur relatively sooner. Additionally, increasing the distance ds will decrease the stiffness of the spoke 200, thus increasing the amount deflection for a given load, which increases the likelihood of contact between adjacent spokes 200. Decreasing the distance ds will have an opposite effect, and will physically move each spoke 200 farther from adjacent spokes 200, thus causing contact between adjacent spokes 200 to occur relatively later. Additionally, decreasing the distance ds will increase the stiffness of the spoke 200, thus decreasing the amount of deflection for a given load, which decreases the likelihood of contact between adjacent spokes 200.

[0065] The distance ds between the transition portion 224 and the center of the first radius of curvature ri of the knee portion 222 along a direction parallel to the base plane pi, affects when contact with adjacent spokes 200 will occur. When the distance ds is a greater percentage of di, this will result in contact between adjacent spokes 200 occurring relatively sooner. When the distance ds is a smaller percentage of di, this will result in contact between adjacent spokes 200 occurring relatively later.

[0066] The radius of curvature ri of the knee portion 222, affects when contact with adjacent spokes 200 will occur. Decreasing the radius of curvature ri will result in contact between adjacent spokes 200 occurring relatively later, while increasing the radius of curvature ri will result in contact between adjacent spokes 200 occurring relatively sooner. The spoke thickness t affects the stiffness of the spoke 200. Increasing spoke thickness t will increase the stiffness of the spoke 200, while decreasing spoke thickness will decreases the stiffness of the spoke 200.

[0067] Additionally, it has been found that vertical stiffness of the tire is affected by the combination of spoke thickness t and the distance ds. Increasing the distance ds decreases tire stiffness, while decreasing the distance ds increases tire stiffness. Consequently, it has been found that, in order to meet a targeted value of tire stiffness, a spoke with a larger thickness t should be combined with a larger distance r/j, while a spoke with a smaller thickness t should be combined with a smaller distance ds.

[0068] Figure 11 is a flow chart showing an exemplary method of manufacturing a non-pneumatic tire. At 1010, a lower ring and an upper ring are provided. The lower ring has a first diameter and the upper ring has a second diameter that is greater than the first diameter. At 1020, a plurality of spokes are formed. The spokes may be formed using hot stamping, cold forming, extruding, rolling, bending, or any other desired method. Additionally, the spokes may be formed using multiple composite fabrication techniques (e.g., high pressure resin transfer molding). Each spoke extends between a first end and a second end. A knee portion is located between the first end and the second end, and a transition portion is located between the first end and the knee portion. The knee portion and the transition portion are concavely curved in opposite facing directions. A foot portion extends from the transition portion.

[0069] At 1030, a flexure member is attached to the spoke. At 1040, the spokes are arranged into a first spoke group and a second spoke group that is axially spaced from the first spoke group. Furthermore, the plurality of spokes of the first spoke group are arranged to be concavely curved relative to a first circumferential direction of the tire, and the plurality of spokes of the second spoke group are arranged to be convexly curved relative to the first circumferential direction of the tire.

[0070] At 1040, the lower ring is connected to the upper ring using the first spoke group and the second spoke group. The foot portion of each of the spokes is attached to the lower ring to connect the first end of each spoke to the lower ring. The flexure member is attached to the upper ring to connect the second end of each spoke to the upper ring. [0071] In alternative embodiments, the foregoing steps may occur in an order other than what is specifically described. In other alternative embodiments, the method may include a greater or fewer number of steps.

[0072] Figures 12 and 12a show another embodiment of a spoke 1200. The spoke 1200 of Figures 12 and 12a is substantially the same as the spoke 200 in Figures 1-10, except for the differences described herein. Accordingly, like features will be identified by like numerals increased by a factor of “1000.” In the spoke 200 shown in Figures 1-10, the second connecting portion 228 is linear. In comparison, the spoke 1200 of Figures 12 and 12a has a curved second connecting portion 1228 with a radius of curvature rj. In comparison to a linear second connecting portion, the curved second connecting portion 1228 in the spoke 1200 of Figures 12 and 12a significantly enhances self-supporting behavior. According to one example embodiment, the radius of curvature rj is 10-50 inches (25-127 cm).

[0073] In addition to the design parameters and resultant changes in performance characteristics discussed above in regard to the spoke 200 shown in Figures 1-10, the radius of curvature rj of the curved second connecting portion 1228 in the spoke 1200 of Figures 12 and 12a can be varied to affect performance. The radius of curvature rj of the curved second connecting portion 1228 and a width w/iexure of the flexure member 1216 interact to affect self-supporting performance. A smaller radius of curvature r? of the curved second connecting portion 1228 decreases self-supporting, thus increasing stress during high impact events. A larger radius of curvature r? of the curved second connecting portion 1228 increases self-supporting, thus decreasing stress during high impact events. This decrease in stress, however, occurs only up to a point. As the radius of curvature r? increases (the limit being the radius of curvature r? equal to infinity, resulting in a straight second connecting portion), the effectiveness of the self-supporting begins to once again decrease.

[0074] The width wjiexure of the flexure member 1216 affects its ability to exert torque at the end of the spoke 1200. This torque acts to straighten the curved second connecting portion 1228 as the tire rolls under a normal load or experiences a high impact event. Consequently, it has been found that a curved second connecting portion 1228 with a smaller radius of curvature r? is optimally matched with a flexure member 1216 having a larger width Wfiexure, while a curved second connecting portion 1228 with a larger radius of curvature r? is optimally matched with a flexure member 1216 having a smaller width w/iexure. The ability of the flexure member 1216 to exert torque on the spoke 1200 is, in addition to the width w/iexure of the flexure member 1216, affected by the stiffness of the material used to manufacture the flexure member 1216. Consequently, it is desirable to provide a flexure member 1216 with a wider width wjiexure when a softer material is used, and to provide a flexure member 1216 with a narrower width w/iexure when a stiffer material is used.

[0075] The non-pneumatic tire described herein improves the robustness of the non-pneumatic tire by providing an arrangement where adjacent spokes contact one another during a high impact event. The contact between adjacent spokes results in multiple spokes sharing a load, thus significantly reducing the stress experienced by any single spoke in the non-pneumatic tire. Thus, the durability of the non- pneumatic tire is improved.

[0076] In the above described embodiment, the foot portion 214 of the spoke 200 is initially substantially straight, and is bonded to the curved external surface 24 of the lower ring 20. This bonding process forces the foot portion 214 to adapt to the curvature of the external surface 24. While this arrangement results in a relatively simple manufacturing process for the spoke 200 and the lower ring 20, it may give rise to other potential design difficulties. For example, in the flat foot portion embodiment, the primary application force acting on the bond between the spoke and the ring is a tensile force. This tensile force may cause a cleavage type failure at a leading edge of the spoke. As another example, the rotational position of each spoke relative to the lower ring and the upper ring cannot be adjusted without undesirably introducing pre-stresses into the spoke.

[0077] Rotational adjustment of the spokes may be necessary to account for manufacturing tolerances. Ideally, every spoke of the non-pneumatic tire would be identical, including the dimensions of various elements (e.g., lengths of foot portion, first connecting portion, and second connecting portion) and also the angles between those elements (e.g., angle between the foot portion and the first connecting portion or between the first and second connecting portions). In practice, however, it is unlikely that every spoke will be identical. Manufacturing guidelines acknowledge variables within formed features of a product, such as material thickness and temper tolerances. Additionally, these manufacturing guidelines acknowledge variables within angular tolerances on bends, with one guideline suggesting a tolerance of +/- one degree.

[0078] Figures 13 and 14 illustrates how this +/- one degree tolerance can affect the support structure of a non-pneumatic tire. The non-pneumatic tire of Figures 13 and 14 is constructed in accordance with the non-pneumatic tire embodiment of Figures 1-6. Accordingly, like features will be identified by like numerals.

[0079] Figures 13 and 14 show a first spoke 200a, a second spoke 200b, and a third spoke 200c. In the first spoke 200a and the third spoke 200c, an angle 0 between the foot portion 214 and the first connecting portion 226 is one degree less than the specified design value, while in the second spoke 200b this angle 0 is one degree greater than the design value. Figure 13 shows the spokes 200 when the foot portion 214 is connected to the lower ring 20 and the second end 208 of each spoke 200 is in a natural or resting position (z.e., the location of the second end 208 of the spoke 200 without the application of any external forces and before the flexure member 216 is attached to the upper ring 30). Figure 14 shows the spokes 200 after the second end 208 of the spoke 200 has been moved to a desired location and the flexure member 216 is attached to the upper ring 30. As shown in Figure 13, having the angle between the foot portion 214 and the first connecting portion 226 out of specification by a single degree can cause various issues, including having the flexure member 216 naturally resting above the upper ring 30 (second spoke 200b) or below the upper ring 30 (first and third spokes 200a, 200c), and having irregular spacing between adjacent spokes 200. Some of these issues can be corrected by forcing the second end 208 of each spoke 200 into a desired position, as shown in Figure 14, but doing so undesirably introduces pre-stresses into the spokes 200. In theory, each spoke 200 could be rotated about its first end 206 to correct these issues. Practically speaking, however, such rotation is not possible due to the geometries between the flat foot portion 214 and the external surface of the lower ring 20.

[0080] Figure 15 shows part of an alternative embodiment of a non-pneumatic tire having features that alleviate the above-identified issues regarding manufacturing tolerances. Figures 16 and 17 show a single spoke of the nonpneumatic tire of Figure 15. The arrangement shown in Figures 15-17 is substantially similar to the arrangement shown in Figures 1-6, except for any differences described herein. Accordingly, like features will be identified by like numerals increased by a value of “2000.”

[0081] The non-pneumatic tire 2010 includes support structure 2100 that connects a lower ring 2020 to an upper ring (not shown). The support structure 2100 is made up of a plurality of spokes 2200 (only a single spoke shown) that are arranged into first spoke and second spoke groups (not shown). The first spoke group and the second spoke group are offset and spaced apart from one another in the axial direction of the non-pneumatic tire 2010.

[0082] Each spoke 2200 extends between a first end 2206 and a second end 2208, and includes a first surface 2210 and a second surface 2212. A flexure member 2216 is provided at the second end 2208 of the spoke 2200. A knee portion 2222 is provided between the first end 2206 and the second end 2208. A first connecting portion 2226 connects the first end 2206 to a knee portion 2222. A second connecting portion 2228 connects the knee portion 2222 to the second end 2208 of the spoke 2200. Unlike the spokes shown in the embodiment of Figures 1-6, the spokes shown in the embodiment of Figures 15-17 do not include a transition portion or a foot portion.

[0083] A boot 2215 is attached to the first end 2206 of the spoke 2200. The boot 2215 may be manufactured out of steels, aluminum, titanium, magnesium, composites (e.g., aluminum metal matrix, carbon fiber, reinforced plastics), or any other desired material, and may be attached to the spoke 2200 using adhesives, mechanical fasteners, a combination of adhesives and mechanical fasteners, welding, or any other desired arrangement. The boot 2215 extends between a first edge 2327 and a second edge 2329. The distance between the first edge 2327 and the second edge 2329 defines a boot width. As used herein, “width” refers to the dimension of a component extending along an axial direction of the non-pneumatic tire 2010. In the illustrated embodiment, the width of the boot 2215, the width of the spoke 2200, and the width of the lower ring 2020 are all equal to one another. In alternative embodiments, the width of the boot, the spoke, and the lower ring may be increased or decreased so that the width of any one of these elements is greater than or less than another one of the elements.

[0084] The boot 2215 includes a first side 2217 and a second side 2219. The first side 2217 includes a first linear roof portion 2221. The second side 2219 includes a second arcuate roof portion 2227. The first and second roof portions 2221, 2227 meet at a peak 2229. The spoke 2200 enters the boot 2215 through an aperture 2231 provided on the second arcuate roof portion 2227. A first wall portion 2233 extends at an obtuse angle from the first roof portion 2221, and a second wall portion 2235 extends at an obtuse angle from the second roof portion 2221. The first and second wall portions 2233, 2235 are both linear and extend parallel to one another. A floor portion 2237 extends between the first wall portion 2233 and the second wall portion 2235. The first end 2206 of the spoke 2200 is spaced from the floor portion 2237 when the spoke 2200 is received in the boot 2215. The boot 2215 may provide a stiffer attachment than embodiments of a spoke with no boot. The design of the boot and the orientation of the spoke relative to the boot may be altered in order to provide the non-pneumatic tire with desired performance characteristics.

[0085] The external surface 2024 of the lower ring 2020 is provided with a plurality of scallops 2025 that are equal in number to the total number of spokes 2200 in the support structure 2100. The floor portion 2237 of the boot 2215 is curved and has a radius of curvature r/ _p that is equal to a radius of curvature r _s of a corresponding scallop 2025. The scallops 2025 are spaced apart from one another along a circumferential direction of the non-pneumatic tire 2010, and are arranged into first and second scallop groups (not shown). Like the separation between the first and second spoke groups, the scallop groups are also offset and spaced apart from one another in the axial direction of the non-pneumatic tire 2010. The floor portion 2237 of the boot 2215 is bonded to a respective scallop 2025 to attach the first end of the spoke 2200 to the lower ring 2020. The flexure member 2216 is bonded to the upper ring 2030 to connect the second end 2208 of the spoke 2200 to the upper ring 2030. In alternative embodiments, the boot or the flexure member may be attached to the scallop or upper ring, respectively, using any desired arrangement.

[0086] The above described arrangement helps resolve the potential design issues associated with the flat foot portion spoke embodiment in regard to spoke manufacturing tolerances. Providing the non-pneumatic tire 2010 with spokes 2200 having a boot 2215 with a curved floor portion 2237 and a corresponding curved scallop 2205 makes the primary application force acting on the bond between the boot 2215 and the lower ring 20 a shear force, rather than the tensile force found in the flat foot portion embodiment. This change reduces the possibility of a cleavage type failure mode occurring at the connection between the spoke 2200 and the lower ring 2020. Furthermore, the shear force acting on the bond between the boot 2215 and the lower ring 2020 puts the bond into a substantially stronger failure mode for the most commonly used adhesives.

[0087] Additionally, the curved floor portion 2237 of the boot 2215 and the scallop 2025 allow for the adjustment of the rotational position of each spoke 2200 relative to the lower ring 2020 and the upper ring 2030 without pre-inducing stresses into the spoke as would be the case for the flat foot portion embodiment. These curved surfaces also allow a constant adhesive gap to be maintained between the boot 2215 and the scallop 2025 during such rotational position adjustment.

[0088] It has been found that the radius of curvature rf _p of the floor portion 2237 and the radius of curvature r _s of the scallop 2025 should conform to certain design principles to provide the above described flexibility regarding rotational position adjustment. According to one example design principle, the radius of curvature rf _p of the floor portion 2237 and the radius of curvature r _s of the scallop 2025 is different from a radius of curvature n _r of the external surface 2024 of the lower ring 2020.

[0089] In the illustrated embodiment, the floor portion 2237 of the boot 2215 and the scallop 2025 are both convex relative to an inner surface 2023 of the lower ring 2020, and the radius of curvature r/ _p of the floor portion 2237 and the radius of curvature r _s of the scallop 2025 are both constant and equal to one another. Additionally, the scallops 2025 are formed directly on the lower ring 2020. In alternative embodiments, the floor portion of the boot may be convex relative to the inner surface of the spoke and the lower ring may be provided with corresponding bumps that are also convex relative to the inner surface of the spoke. In other alternative embodiments, the radius of curvature of the floor portion or the radius of curvature of the scallop or bump may be variable or different from one another. In still other alternative embodiments, the scallops or bumps may be formed on a sleeve that is secured to the external surface of the lower ring.

[0090] Additionally, it has been found that the boot may be used without scallops on the inner ring. In such an arrangement, the floor portion of the boot has a shape that compliments the shape of the external surface of the lower ring. According to one non-limiting example where scallops are not used, the floor portion of the boot has a radius of curvature that is substantially the same as the radius of curvature of the external surface of the lower ring. Furthermore, it has been found that the scallops on the lower ring may be other shapes than curved. According to one non-limiting example, the scallops may be provided as flat portions on the external surface of the lower ring. In this arrangement, the floor portion of the boot would be flat in order to compliment the flat portions on the lower ring.

[0091] Figure 18 shows a variation of a boot 3215 for a non-pneumatic tire. The boot 3215 of Figure 18 is substantially the same as the boot 2215 shown in the non-pneumatic tire 2010 of Figures 15-17 except for the differences described herein. Accordingly, like features will be identified by like numerals increased by a factor of “1000.” [0092] The boot 3215 includes a first side 3217 and a second side 3219. The first side 3217 includes a first linear roof portion 3221. The second side 3219 includes a second step-shaped roof portion 3227. The first and second roof portion 3221, 3227 meet at a peak 3229. The spoke 3200 enters the boot through an aperture 3231 provided on the second roof portion 3227. The aperture 3231 extends the full width of the boot 6548, and separates the second roof portion 3227 into a first step 3227a and a second step 3227b. A linear wall portion 3235 extends at a substantially right angle from the second step 3227b. The wall portion 3235 extends substantially parallel to the first roof portion 3221. A linear ceiling portion 3239 extends at an arcuate angle from the wall portion 3235. Together, the linear ceiling portion 3239 and the wall portion 3235 define a substantially V-shaped notch. A floor portion 3237 extends between the first roof portion 3221 and the ceiling portion 3239. The floor portion 3237 has a radius of curvature r/ _p that is equal to a radius of curvature r _s of a corresponding scallop 3025 provided on an external surface 3024 of the lower ring 3020.

[0093] The particular arrangement of the boot 3215 may allow for tuning of localized stiffness of the boot 3215 to reduce peak stresses in the adhesive or other fastening arrangement. This reduction in peak stresses may be provided by the V- shaped notch that is defined by the linear ceiling portion 3239 and the wall portion 3235. The design of the boot and the orientation of the spoke relative to the boot may be altered in order to provide the non-pneumatic tire with certain desired performance characteristics. For example, increasing the size of the V-shaped notch may decrease stiffness of the boot, while decreasing the size of the notch may incease the stiffness of the boot. As another example, changing where the spoke enters the boot may also alter the stresses in the boot and the adhesives or other fastening arrangement.

[0094] Figure 19 shows an end cap 5000 that can be used with a spoke 5002 having a boot 5004. The end cap 5000 may be provided to limit adhesive “squeeze- out” during the bonding process between the boot and the lower ring 5003. Additionally, the end cap may act as a structural member that strengthens the boot 5004 [0095] The end cap 5000 may be manufactured out of metals, composites, plastics, rubber, polymer, or any other desired material or combination of materials. The end cap 5000 includes a boot mating surface 5006 and an external facing surface 5008. The boot mating surface 5006 is attached to the boot 5004 to secure the end cap 5002 to the boot 5004. This attachment may be achieved using adhesives, mechanical fasteners, a combination of adhesives and mechanical fasteners, or any other desired fastening arrangement. The external facing surface 5008 may be plain, or may be provided with functional features or with decorative features (e.g., corporate logo).

[0096] The end cap 5000 includes a first roof portion 5010 and a second roof portion 5012 that meet at a peak 5014. A first wall portion 5016 extends from the first roof portion 5010, and a second wall portion 5018 extends from the second roof portion 5012. A floor portion 5020 extends between the first wall portion 5016 and the second wall portion 5018. In the illustrated embodiment, the profile of the end cap 5000 is substantially the same as the profile of the boot 5004 to which the end cap 5000 is attached. In alternative embodiments, the end cap 5000 may have any desired profile (z.e., profile different from that of the boot).

[0097] Figures 20-22 show another embodiment of a boot 4215 for a nonpneumatic tire. The boot 4215 is similar to the boot 2215 shown in the nonpneumatic tire 2010 of Figures 15-17 except for the differences described herein. Accordingly, like features will be identified by like numerals increased by a factor of “2000.”

[0098] The boot 4215 includes a first part 4217 and a second part 4219. The first and second parts 4217, 4219 are separate, discrete components. The first and second parts 4217, 4219 define a gap 4231 that receives a spoke 4200. When so received, the spoke 4200 is sandwiched between the first and second parts 4217, 4219

[0099] The first part 4217 includes a linear roof portion 4221 and a floor portion 4237. The floor portion 4237 has a radius of curvature r/ _p that is substantially equal to a radius of curvature r _s of a corresponding scallop 4025 provided on an external surface 4024 of the lower ring 4020. Each first part 4217 is connected to the lower ring 4020 by two first fasteners 4270. An adhesive (not shown) may be used to augment the connection between the first part 4217 and the lower ring 4020 by bonding the floor portion 4237 to the scallop 4025. The adhesive may prevent wear between the various components due to cyclic loading and may also prevent degradation (e.g., corrosion) resulting from exposure to environmental elements. In alternative embodiments, the first part may have any desired form (e.g., curved roof portion).

[0100] In the illustrated embodiment, each first fastener 4270 is provided as an assembly that includes a threaded rod, a washer, and a nut. The threaded rod engages internal threads provided on the first part 4217. In alternative embodiments, each first fastener may have any desired arrangement (e.g., socket head cap screw, two nuts provided on opposite ends of the threaded rod rather than the internal threads on the first part, and screws or flanged studs that pass through the first part and thread into internal threads provided on the lower ring). In other alternative embodiments, each of the first fasteners may be provided with a different arrangement (e.g., threaded rod , washer, and nut for one of the first fasteners and socket head cap screw for the other one of the first fasteners). In still other alternative embodiments, there may be a greater or fewer number of first fasteners. [0101] The first fastener 4270 extends through the lower ring 4020, the floor portion 4237, and the linear roof portion 4221. When so arranged, the floor portion 4237 is attached to the lower ring 4020. In alternative embodiments, the first fastener, the lower ring, and/or the first part may be dimensioned and configured so that the first fastener does not extend through the floor portion or the linear roof portion. For example, the first fastener may be made shorter so that the first fastener terminates within the first part rather than extending through the linear roof portion. [0102] The second part 4219 is attached to the first part 4217 by a plurality of second fasteners 4272. The second fasteners 4272 also attach the spoke 4200 to the boot 4215. In the illustrated embodiment, the second fasteners 4272 are eight socket head cap screws that are aligned with one another. The threads of the socket head cap screws engage internal threads provided on the second part 4219. In alternative embodiments, the second fasteners may have any desired arrangement (e.g., a nut that engages with the threads of the socket head cap screws rather than the internal threads on the second part). In other alternative embodiments, there may be a greater or fewer number of second fasteners. In still yet other alternative embodiments, the second fasteners may be offset from one another.

[0103] The second fasteners 4272 extend through the linear roof portion 4221 of the first part 4217, the spoke 4200, and a wall portion 4235 of the second part 4219. According to this arrangement, the spoke 4200 is effectively clamped between the first part 4217 and the second part 4219. An adhesive (not shown) may augment the connection between the first and second parts 4217, 4219 and the spoke 4200 by bonding these components together. The adhesive may prevent wear between the various components due to cyclic loading and may also prevent degradation (e.g., corrosion) resulting from exposure to environmental elements. In alternative embodiments, the second fasteners, the second part, the spoke, and the first part may be dimensioned and configured so that the second fastener does not extend through the wall portion of the second part or the linear roof portion of the first part. For example, the second fasteners may be made shorter so that the second fasteners terminate within the second part rather than extending through the wall portion. In other alternative embodiments, the orientation of the second fasteners may be reversed so that the second fasteners extend through the second part, then the spoke, and engage with internal threads provided on the first part. In still other alternative embodiments, depending on the material used to manufacture the spoke, the second part may be omitted. According to this example, the second fasteners may include a nut and bolt with the nut engaging a surface of the spoke, or threaded part of the second fasteners may engage with internal threads provided on the spoke.

[0104] Thus, the spoke 4200 is attached to the lower ring 4020 by the boot 4215, which is collectively made up of the first and second parts 4217, 4219, the first fastener 4270, and the second fasteners 4272. In particular, the first and second parts 4217, 4219 and second fasteners 4272 attach the boot 4215 to the spoke 4200, and the first fastener 4270 attaches the floor portion 4237 to the lower ring 4020. This arrangement provides a robust attachment mechanism for the spoke, and allows for the individual removal, maintenance, and installation of a single spoke. Additionally, the arrangement does not encroach the region of the spoke that is designed to deflect, thereby ensuring that the non-pneumatic tire properly carries an applied load.

[0105] While discrete embodiments and variants have been shown and described in Figures 1-22, the disclosed features not exclusive to each described embodiment. Instead, various features can be combined between the embodiments as desired. For example, the arrangement of the spokes with boots shown in Figures 15-17 may be combined with the curved connecting portion of the spoke shown in Figures 12 and 12a.

[0106] To the extent that the term “includes” or “including” is used in the specification or the claims, it is intended to be inclusive in a manner similar to the term “comprising” as that term is interpreted when employed as a transitional word in a claim. Furthermore, to the extent that the term “or” is employed (e.g., A or B) it is intended to mean “A or B or both.” When the applicants intend to indicate “only A or B but not both” then the term “only A or B but not both” will be employed. Thus, use of the term “or” herein is the inclusive, and not the exclusive use. See, Bryan A. Garner, A Dictionary of Modern Legal Usage 624 (2d. Ed. 1995). Also, to the extent that the terms “in” or “into” are used in the specification or the claims, it is intended to additionally mean “on” or “onto.” Furthermore, to the extent the term “connect” is used in the specification or claims, it is intended to mean not only “directly connected to,” but also “indirectly connected to” such as connected through another component or components.

[0107] While the present application has been illustrated by the description of embodiments thereof, and while the embodiments have been described in considerable detail, it is not the intention of the applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art. Therefore, the application, in its broader aspects, is not limited to the specific details, the representative apparatus and method, and illustrative examples shown and described. For example, each spoke may be provided with a rubber coating to soften impact when contact between adjacent spokes occurs. Accordingly, departures may be made from such details without departing from the spirit or scope of the applicant’s general inventive concept.