Single wheel self-balancing vehicle with tire permitting carving motion

Abstract

In an aspect, a tire for use with a single wheel, self-balancing vehicle is provided. The tire has a tire body with a tread configured for engagement with a ground surface. The tread has a lateral profile having a central region, a first lateral region tapering towards a first lateral side of the tire, and a second lateral region tapering towards a second lateral side of the tire. The lateral profile is substantially free of discontinuity. The tread has a non-directional tread groove arrangement that is asymmetrical about a central circumference line of the tire. The tire has a hardness selected to substantially prevent deformation of the first profile and the second profile during riding by a rider.

Claims

1. A tire for use with a single wheel, self-balancing vehicle that has a platform, wherein the tire has a tire body with a tread configured for engagement with a ground surface, the tread having a lateral profile having a central region, a first lateral region tapering towards a first lateral side of the tire, and a second lateral region tapering towards a second lateral side of the tire, wherein the lateral profile is substantially free of discontinuity, when the platform and the ground surface are level horizontally, a contact patch between the tire and the travel surface extends along a width of the central region, the tread having a tread groove arrangement that is asymmetrical about a central circumference line of the tire, the tire having a hardness selected to substantially prevent deformation of the first profile and the second profile during riding by a rider, wherein the tread groove arrangement comprises a first pattern of grooves on a first side of and adjacent the central circumference line and a second pattern of grooves on a second side of and adjacent the central circumference line, wherein the first pattern of grooves includes a plurality of first lateral grooves each of which extends from the central circumference line continuously laterally through the central region into the first lateral region, wherein the second pattern of grooves includes a plurality of second lateral grooves each of which extends from the central circumference line continuously laterally through the central region into the first lateral region, and wherein the first lateral grooves are circumferentially off-phase from the second lateral grooves.

2. A tire according to claim 1, wherein the tread groove arrangement comprises at least one circumferential groove.

3. A tire according to claim 2, wherein the plurality of first lateral grooves, the plurality of second lateral grooves, and the at least one circumferential groove make up the entirety of the tread groove arrangement.

4. A tire according to claim 3, wherein each of the at least one circumferential groove in the tread groove arrangement is spaced from the central circumferential line.

5. A tire according to claim 1, wherein the central region of the lateral profile is generally flat.

6. A tire according to claim 5, wherein the central region has a width of at least 25 percent of a lateral width of the tread.

7. A tire according to claim 6, wherein the central region has a width of at most 50 percent of a lateral width of the tread.

8. A tire according to claim 1, wherein the tire is solid.

9. A tire according to claim 8, wherein the tire is comprised of a rubber.

10. A tire according to claim 1, wherein the tire has a hardness of at least about Shore 56A.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Embodiments will now be described, by way of example only, with reference to the attached Figures, wherein:

(2) FIG. 1 is a side perspective view of a single wheel, self-balancing board employing a prior art tire;

(3) FIG. 2A is a front sectional view of the tire of the single wheel, self-balancing board of FIG. 1 in contact with a travel surface with a rider's weight evenly distributed between lateral sides of the platform of the single wheel, self-balancing board of FIG. 1;

(4) FIG. 2B is a front sectional view of the tire of the single wheel, self-balancing board of FIG. 1 in contact with a travel surface with a rider's weight shifted to a lateral side of the platform of the single wheel, self-balancing board of FIG. 1;

(5) FIG. 3A shows a top view of a single wheel, self-balancing board employing a tire in accordance with an embodiment;

(6) FIG. 3B shows a side view of the single wheel, self-balancing board of FIG. 3A;

(7) FIG. 4 is a lateral profile of a tread of the single wheel from the single wheel, self-balancing board of FIG. 3A;

(8) FIG. 5 shows a top view of the tire of FIG. 3A;

(9) FIG. 6A is a sectional view along line 6A-6A of FIG. 5;

(10) FIG. 6B is a sectional view along line 6B-6B of FIG. 5;

(11) FIG. 6C is a sectional view along line 6C-6C of FIG. 5;

(12) FIG. 7 illustrates a top view of a travel path of the single wheel, self-balancing board of FIG. 3A;

(13) FIG. 8A shown a lateral orientation of the single wheel, self-balancing board at line 8A-8A in FIG. 7;

(14) FIG. 8B shown a lateral orientation of the single wheel, self-balancing board at line 8B-8B in FIG. 7; and

(15) FIG. 8C shown a lateral orientation of the single wheel, self-balancing board at line 8C-8C in FIG. 7.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(16) FIGS. 3A and 3B show a single wheel, self-balancing vehicle 100 employing a tire in accordance with an embodiment of the present disclosure. The vehicle 100 facilitates riding in a carving motion as shown in FIG. 7, similar to that performed on a snowboard or surfboard. The single wheel, self-balancing vehicle 100 has a platform 104 that has a pair of foot deck surfaces 108 that are bridged by a pair of lateral frame members 112. The foot deck surfaces 108 and the lateral frame members 112 define a wheel opening 116. A motorized wheel assembly 120 is rotationally coupled to the platform 104 and is powered to transport a rider standing on the platform along a ground surface. The wheel assembly 120 is positioned in the wheel opening 116 and secured to the lateral frame members 112 by an axle 124 that spans the lateral frame members 112. The wheel assembly 120 has a tire 128 that is mounted on a motorized hub 132. The axle 124 defines a rotation axis 136 for the tire 128.

(17) A set of laterally extending cylindrical through holes 140 extend directly laterally through the width of the tire 128 between opposite lateral sides 144a, 144b (collectively, lateral sides 144) through the tire 128. The cylindrical through holes 140 reduce the weight of the tire 128 without significantly compromising its resistance to deformation.

(18) The tire 128 has a tread 148 having a tread groove arrangement 152 formed thereon.

(19) As shown in FIG. 5, the tread 148 has a central region 153 that may have a generally flat lateral profile; that is, all lateral points of the central region 153 are generally radially equidistant from the rotation axis 136. When the platform 104 and a travel surface upon which it is positioned are level horizontally, the contact patch between the tire 128 and the travel surface 64 extends the width of the central region 153.

(20) Two lateral regions 154 of the tread 148 extend and taper smoothly from the central region 153 towards the lateral sides 144 of the tire 128.

(21) As a result of the above, the tread 148 has a lateral profile shown at 300 in FIG. 4, including a central region 302 and first and second lateral regions 304 and 306. The first lateral region 304 tapers towards a first lateral side of the tire 128, and the second lateral region 306 tapers towards a second lateral side of the tire 128. The lateral profile 300 is substantially free of discontinuity. This means that, along the lateral profile, there are no points of discontinuous slope change. A corollary to this statement is that there is no discontinuity at the transition between the central region 302 of the lateral profile and each of the two lateral regions 304 and 306.

(22) The width of the central region 153 may be about 46 percent of the lateral width of the tire 128 (shown at W in FIG. 6A), and the width of each of the lateral regions 154 is about 32 percent of the lateral width of the tire 128. The width of the central region 153 of the tread 148 corresponds to the width of the central region 302 of the lateral profile 300. Similarly, the widths of the lateral regions 154 of the tread 148 corresponds to the width of the lateral regions 304 and 306 of the lateral profile 300. The width of the central regions (i.e. regions 153, 302), can be varied relative to the widths of the lateral regions (i.e. regions 154, 304, 306). For example, in some embodiments, it can be desirable to have the width of the central region 153 be about 25 percent of the tire 128, or greater in some embodiments.

(23) The generally flat central region 153 facilitates straight-ahead travel of the tire 128 when weight is generally evenly distributed between lateral sides of the platform 104 by a rider, so as to maintain a generally level lateral orientation of the platform 104 as shown in FIG. 3B.

(24) Providing a lateral profile without discontinuities enables a rider to smoothly transition between travel on the central region 153 and the lateral regions 154 without an abrupt change in the lateral angle of the vehicle 100. Such abrupt changes in some boards of the prior art can render the boards difficult to control and particularly difficult to ride in a carving motion, as shown in FIG. 7.

(25) As shown in FIGS. 5 and 6A-6C, the tread groove arrangement 152 has a set of four continuous circumferential grooves 156a, 156b, 156c, and 156d (collectively referred to as circumferential grooves 156) that are spaced from a central circumference line 160 that is equidistant from the lateral sides 144 of the tire 128.

(26) Further, the tread groove arrangement 152 is asymmetrical about the central circumference line 160. That is, the tread groove arrangement 152 on one side of the central circumference line 160 does not mirror the tread groove arrangement 152 on the opposing side of the central circumference line 160. In particular, the tread groove arrangement 152 on one side of the central circumference line 160 has a first pattern of grooves adjacent the central circumference line 160 that is out of alignment with a second pattern of grooves adjacent the central circumference line 160 in the tread groove arrangement 152 on the opposing side of the central circumference line 160. As a result, the tire 128 does not have a central ridge.

(27) In the example shown, the first pattern of grooves is made up of a first set of lateral grooves 164a that are spaced around the circumference of the tire 128 and extend from the central circumference line 160 towards the lateral side 144a in combination with the circumferential grooves 156a and 156b. In the example embodiment shown in FIG. 5, the first set of lateral grooves 164a are spaced at 14.4 degree intervals around the circumference of the tire 128 relative to the rotation axis 136.

(28) In the example shown, the second pattern of grooves is made up of a second set of lateral grooves 164b that are spaced around the circumference of the tire 128 and extend from the central circumference line 160 towards the other lateral side 144b in combination with the circumferential grooves 156a and 156b. The second set of lateral grooves 164b may also be spaced at 14.4 degree intervals around the circumference of the tire 128 relative to the rotation axis 136, but are off-phase about the circumference of the tire 128 relative to the first set of lateral grooves 164a. As a result, the lateral grooves 164a, 164b provide breaks adjacent the central circumference line 160 of the tire 128 on alternating sides of the central circumference line 160 about the circumference of the tire 128.

(29) In the example embodiment shown, the lateral grooves 164a and 164b extend solely laterally. However there are other arrangements of grooves that would provide the desired performance characteristics of the vehicle 100.

(30) FIG. 6A shows a cross section of a portion of tire 128 along line 6A-6A of FIG. 5. Line 6A-6A coincides with one of the lateral grooves 164a extending from the central circumference line 160 towards the lateral side 144a, and does not coincide with one of the lateral grooves 164b extending from the central circumference line 160 towards the lateral side 144b.

(31) FIG. 6B shows a cross section of a portion of tire 128 along line 6B-6B of FIG. 5. Line 6B-6B does not coincide with any of the lateral grooves 164a or the lateral grooves 164b.

(32) FIG. 6C shows a cross section of a portion of tire 128 along line 6C-6C of FIG. 5. Line 6C-6C coincides with one of the lateral grooves 164b extending from the central circumference line 160 towards the lateral side 144b, and does not coincide with one of the lateral grooves 164a extending from the central circumference line 160 towards the lateral side 144a.

(33) The asymmetry in the tread groove arrangement 152 about the central circumference line 160 permits generally stable motion of the tire 128 in straight-ahead motion, but facilitates leaning the tire 128 to lift off from the central region 15e of the tread 148 and to lean on either of the lateral regions 154 of the tread 148. As a result, when a rider's weight is shifted to one lateral side of the platform 104 and the corresponding lateral region 154 is in contact with a generally flat travel surface, shifting of the rider's weight to the opposite lateral side of the platform 104 causes the single wheel, self-balancing vehicle 100 to be transition smoothly from an orientation in which it leans to one side through an orientation where it is generally level, to an orientation in which it leans to the other side.

(34) Additionally, it can be seen that the tread groove arrangement 152 is non-directional; that is, the tread groove arrangement 152 is not a directional tread groove arrangement.

(35) Directional tread groove arrangements can be undesirable as they have been found to possess generally undesirable turning characteristics when attempting to generate a carving motion during operation of the one-wheeled vehicle 100.

(36) Further, the tire 128 is resistant to compression so that deformation of the profile of the tire 128 is substantially prevented for a given weight of rider. In the example embodiment shown, the tire 128 may be a solid (non-pneumatic) tire, made from any suitable material such as a suitable rubber. The tire 128 has a hardness that is selected to substantially prevent deformation of the profiles of the lateral regions 154 when the rider is riding on either of them. The aforementioned feature of substantially preventing deformation may be defined specifically to mean that deformation is substantially prevented when the vehicle 100 is ridden by a rider who weighs at least 110 pounds. Substantially preventing deformation may mean, in at least some embodiments, that any overall dimension associated with the tire 128 (e.g. overall width, overall side wall height). does not change by more than 10 percent when the board is being ridden by the aforementioned rider of at least 110 pounds. Depending on the application substantially preventing deformation may mean that any dimension associated with the tire 128 does not change by more than 5 percent. Depending on the application substantially preventing deformation may mean that any dimension associated with the tire 128 does not change by more than 5 percent when being ridden by the aforementioned rider. In other embodiments, a different percentage of deformation that is greater than 10 percent or less than 5 percent may be acceptable.

(37) The cylindrical through holes 140 do not significantly impact the compressibility/deformation of the tire 128. In one scenario, it has been found that a suitable rubber or rubber compound having a hardness of at least about Shore 58A under the rubber durometer scale provides a desirable resistance to deformation for the tire 128 for riders up to about 155 pounds. In other embodiments, the hardness of the tire 128 may be selected to be sufficient to substantially prevent deformation for a rider of, for example, at least 110 pounds. The appropriate hardness of the rubber of a tire can vary based on the dimensions and design of the wheel, the weight of the rider, and other parameters. and can be determined through experimentation. In some embodiments, the tire can have a hardness of as little as Shore 56A durometer. In some embodiments, the tire can have a hardness of Shore 60A durometer.

(38) The tire 128 permits the vehicle 100 to be ridden in a carving motion so as to provide a surfing- or snowboarding-like experience for the rider. The motion illustrated by the path shown FIG. 7 is not simply achieved by steering the front of the vehicle 100 so that its longitudinal axis is pushed or pulled by the rider directly laterally. The exemplary travel path 200 shown in FIG. 7 is achieved while the rider is generally leaning but is oriented generally such that their sagittal plane is parallel to the general direction of travel shown at D in FIG. 7 of the single wheel, self-balancing vehicle 100. As shown, the travel path 200 swings left, then right, then back to an intermediate position.

(39) FIG. 8A shows the lateral orientation of the single wheel, self-balancing vehicle 100 at line 8A-8A in FIG. 7. At this point along the travel path 200, the single wheel, self-balancing vehicle 100 is to the left of the center of mass 204 of the rider. That is, the rider's weight is shifted to the right side of the platform 104. As a result, the platform 104 is laterally tilted so that the tire 128 is in contact with the travel surface along a portion of the lateral region 154 closest the center of mass 204 of the rider. As the lateral region 154 is somewhat frustoconical, the single wheel, self-balancing vehicle 100 veers to the right.

(40) FIG. 8B shows the lateral orientation of the single wheel, self-balancing vehicle 100 at line 8B-8B in FIG. 7. At this point along the travel path 200, the single wheel, self-balancing vehicle 100 is under the center of mass 204 of the rider. Here, the rider is distributing weight generally evenly laterally across the platform 104. As a result, the platform 104 is level horizontally so that the central region 153 is in contact with the travel surface. The single wheel, self-balancing vehicle 100, however, traveling in a direction that varies from the direction that the rider's center of mass is traveling.

(41) FIG. 8C shows the lateral orientation of the single wheel, self-balancing vehicle 100 at line 8C-8C in FIG. 7. At this point along the travel path 200, the single wheel, self-balancing vehicle 100 is to the right of the center of mass 204 of the rider. That is, the rider's weight is shifted to the left side of the platform 104. As a result, the platform 104 is laterally tilted so that the tire 128 is in contact with the travel surface along a portion of the lateral region 154 closest the center of mass 204 of the rider. As the lateral region 154 is slightly frustoconical, the single wheel, self-balancing vehicle 100 veers to the left.

(42) As will be appreciated, the single wheel, self-balancing vehicle 100 transitions through direction changes smoothly.

(43) While, in the above-described embodiment, the tire has a central region, it will be appreciated that a tire can be made without a central region in other embodiments, with the lateral regions abutting each other along a central circumference line.

(44) Persons skilled in the art will appreciate that there are yet more alternative implementations and modifications possible, and that the above examples are only illustrations of one or more implementations. The scope, therefore, is only to be limited by the claims appended hereto.