CA2613834A1 - System and method for providing gyroscopic stabilization to a two-wheeled vehicle - Google Patents

Abstract

This invention provides a stabilizing system and method for two-wheeled vehicles (typically small, human-powered bicycles) that affords the rider no restriction on the full range of movements (banks, leans, etc.) common to bicycles, but that provides greater stability during turns and other maneuvers so that an unintentional bank or tilt (poten¬ tially causing a fall) is less likely, even at relatively slow speeds and startup. A rotating mass of predetermined mass-value and radial mass-distribution is provided coaxially with the front axle. The mass is supported on bearings so as to freewheel with respect to the rotation of the front wheel. As such it can be induced to spin significantly faster than the front wheel thereby generating a gyroscopic effect at the front wheel about the axle. This gyroscopic effect influences the steering of the wheel by the rider. Due to precession, the wheel tends to follow any excessive bank by the bicycle, ensuring that the rider can "steer-out-of " an unintended tilt or bank. Likewise, the gyroscopic effect limits the rider's ability to execute excessive steering, thereby preventing jackknife movements.

Description

SYSTEM AND METHOD FOR PROVIDING GYROSCOPIC
STABILIZATION TO A TWO-WHEELED VEHICLE
BACKGROUND OF THE INVENTION

Field of the Invention This invention relates to stabilization systems for two-wheeled vehicles and train-ing devices for new riders of such vehicles.

Background Information Learning to ride a bicycle, or similar human-powered vehicle, is one of the more difficult physical challenges faced by young children (and some older ones).
Children io must develop awareness of what are, in essence, complex Newtonian principles of force-balance, gravity, torque, inertia and momentum. Only by continually adjusting weight and balance for the prevailing velocity and turn radius can one proficiently ride a bicycle for any distance. Starting a bicycle from a standing position is a particular challenge as the forward velocity needed to maintain balance has not yet been established.
Likewise, turns are difficult for new riders as the weight and balance of the bicycle and rider shiits suddenly and may become difficult to control. It is not uncommon for new riders to jackknife the bicycle wheel, causing both bike and rider to tumble over.

The time-tested approach to preparing children to ride by exposing them to the basic dynamics of a bicycle is the use of training wheels. Briefly, training wheels are typically a pair small-diameter, hard rubber/plastic/ wheels attached by removable brack-ets to the rear axle. When properly installed, the training wheels each extend outwardly (in an axial direction) from a respective axle end several inches, and are mounted so that their lowest points are slightly above the contact point of the rear wheel with the ground.
In this manner, the training wheels allow the rider to lean slightly in either direction with one training wheel, or the other, engaging the ground to prevent the bicycle for tipping further.

While training wheels may be good first step for young riders, the traditional rit-ual of removing them, and allowing the rider to ride therewithout is often fraught with peril and scraped knees. Basically, the rider must now experience a new range of dynam-ics that were unknown while the training wheels were still attached.
Generally, training wheels are inadequate because they do not simulate real, unrestricted bicycle movement.
They incorrectly teach riders to balance by relying on the training wheels rather than ac-tually learning to balance through weight manipulation. Moreover, training wheels in-hibit rider's from banking as they turn, forcing them into bad habits. They rely on the training wheels, making the transition to autonomous riding extremely difficult.

It is highly desirable to provide a training device that can be used following, or as a substitute to, training wheels that allows new riders to experience the full range of dy-namic forces associated with riding while still providing a degree of safety during startup turns and slow riding. In particular, a device that enables children to ride stably at the relatively slow speed of between 2.5 and 5 mph (common for most new riders) while still feeling the stability and behavior of a faster moving bike (e.g. 10 mph+) is highly desir-able.

SUMMARY OF THE INVENTION

This invention overcomes the disadvantages of the prior art by providing a stabi-lizing system and method for two-wheeled vehicles (typically small, human-powered bi-cycles) that affords the rider no restriction on the full range of movements (banks, leans, etc.) common to bicycles, but that provides greater stability during turns and other ma-neuvers so that an unintentional bank or tilt (potentially leading to a fall) is less likely, even at relatively slow speeds and startup. A rotating mass of predetermined mass-value and radial mass-distribution is provided (in an illustrative embodiment) coaxially with the front axle. The mass is supported on bearings so as to freewheel with respect to the rota-tion of the front wheel. As such it can be induced to spin significantly faster than the front wheel thereby generating a gyroscopic effect at the front wheel about the axle. This gyroscopic effect influences the steering of the wheel by the rider. Due to precession, the wheel tends to follow any excessive bank by the bicycle, ensuring that the rider can "steer-out-of' an unintentional tilt. Likewise, the gyroscopic effect limits the rider's abil-ity to execute excessive steering, thereby preventing jackknife movements.

In an illustrative embodiment, mass is mounted on bearings that are themselves mounted over the center hub of the bicycle wheel. The bicycle wheel is, in turn, mounted s conventionally on a threaded axle that is attached to the front fork by opposing nuts. The mass of this embodiment is unpowered, and initially forced in to rotation by action of a helper (adult) as the rider starts the ride. It can be urged to rotate using a variety of per-manently attached and/or detachable mechanisms. One such mechanism employs a wrapped cord and a reel with a ratchet system that locks the reel in a cord-pulling direc-tion and a spring that rewraps the cord in an opposite, cord-retracting direction. Alterna-tively, a removable rack and mass-mounted pinion can be used to rotate to mass. In an-other alternative embodiment, the mass can be rotated using a drill or other cord-less/corded electrical device having an elastomeric attachment (or gear) that engages an appropriate drive hub on the mass. The attachment is inserted into contact with the hub is for a small duration in which rotational motion is imparted to the drive hub from the elec-trical device. The device is then removed. The mass may rotate for a minute or more given proper bearings and balance.

In another embodiment, the mass can be permanently and selectively powered us-ing, for example, a motor assembly that is coaxial with the wheel hub. A
battery or other power source can be attached to the vehicle to provide continuous power. Such a pow-ered implementation may be particularly suited for and adapted to disabled or older riders who require extra assistance. In addition, in alternate embodiments it is expressly con-templated that the rotating mass (powered or unpowered) can be provided non-coaxially within the structure of the steerable front wheel. Appropriate mountings and/or spaces can be provided to allow the non-coaxial mass to rotate appropriately free of interference from the moving wheel.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention description below refers to the accompanying drawings, of which:
Fig. 1 is a side view of a bicycle equipped with a stabilizing system according to an illustrative embodiment of this invention;
Fig. 2 is a fragmentary side view of a front wheel for the bicycle of Fig. 1 includ-ing the stabilizing system having a rotating mass according to one embodiment;
Fig. 2A is a fragmentary side view of a front wheel for the bicycle of Fig. 1 in-cluding the stabilizing system having a rotating mass according to another embodiment;
Fig. 3 is a cross section of the wheel and rotating mass according to either Fig. 2 io or Fig. 2A;
Fig. 4 is a partially exposed perspective view of a cord-pull, recoil-type mecha-nism for initiating rotation of the mass according to an embodiment of this invention;
Fig. 5 is a fragmentary side view of an electrical device-driven mechanism for ini-tiating rotation of the mass according to another embodiment of this invention;
is Fig. 5A is a fragmentary side view of the electrical device-driven mechanism of Fig. 5 with an alternative drive hub design according to another embodiment of this in-vention;
Fig. 6 is a schematic diagram showing the various rotations and axes of interest on a bicycle in connection with this invention;
20 Fig. 7 is a side view of a bicycle and rider in a starting position employing the system and method of this invention;
Fig. 8 is a front view of the bicycle and rider of Fig. 7 now in motion, and experi-encing an imbalance;
Fig. 9 is a front view of the bicycle and rider of Fig. 7 in which the imbalance of 25 Fig. 8 has induced an unintentional bank or tilt;
Fig. 10 is a front view of the bicycle and rider of Fig. 7 in which the unintentional bank or tilt of Fig. 9 is being compensated by precession of the rotating mass to cause the rider to gently steer into the bank;
Fig. 11 is an on-angle view of the bicycle and rider of Fig. 7 showing the recovery 30 from the imbalance due to the steering of Fig. 10;

Fig. 12 is a graph comparing experimental data of upright travel (without rider)for the same bicycle with no rotating mass, a still mass and a properly rotating mass; and Fig. 13 is a graph comparing experimental data of travel path (with two different riders) for the same bicycle with no rotating mass, and a properly rotating mass.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS
A bicycle 100 having a stabilizing system according to an illustrative embodiment of this invention is shown in Fig. 1. This bicycle is exemplary of a certain size and style of human-powered two-wheeled vehicle that is particularly adapted for smaller children.
The terms "bicycle" and "vehicle" as used herein are expressly intended to refer to any type of two-wheeled vehicle (including certain powered vehicles) that would benefit from the front-wheel gyroscopic stabilizing effect to be described herein.

The bicycle 100 includes a conventionally mounted rear wheel assembly 102, driven by a chain 104 that is, in turn operatively connected to a pedal crank assembly 106. The bicycle frame 108 is constructed from a set of joined tubular members that sup-port a seat 110 above the frame 108 and is general alignment with the pedal crank assem-bly 106 so that a rider (see below) can reach and operate the pedals with his or her feet.

The front of the frame 108 includes a down-tube with internal bearings (not shown) that rotatably supports a front fork assembly 122 operatively connected to han-dlebars 124 of conventional design. On the lower end of the fork assembly 120, a front wheel 130 assembly is rotatably mounted. In this embodiment, the front wheel assembly 130 includes an outer hub 132 upon which is mounted a tire (and inner tube-not shown) 134. The outer hub 132 is supported radially and axially with respect to an inner hub 136 by a set of spokes 138. The inner hub is attached to the fork assembly's lower fork ends 140 as described further below. The attachment allows the inner hub 136 to rotate freely so that the bicycle can move in forward and reverse motion (forward motion being gener-ally driven by the rear wheel assembly 102). Likewise, the handlebars rotate within a predetermined range (at least) about the steering axis (dashed line SA) to allow the front wheel to turn with respect to the frame.

Notably, the front wheel assembly 130 includes a rotating mass or "flywheel"
as-sembly160 mass according to an embodiment of this invention. With reference also to Fig. 2, the mass 160 is a circular disk 162 having a width (described below) that is nested within and passes freely between spokes 138 on each of opposing sides of the front wheel assembly 130. The outside diameter DM of the mass disk 162 is small than the inner di-ameter DOH of the outer hub 132. The difference between diameters is sufficient to al-low the outside perimeter edge 210 of the disk 162 to clear the convergence of the spokes 138 that join along the narrowed outer hub from each of opposing sides of the wider inner hub 136. In other words, the spokes generally define an equilateral triangle with the apex io adjacent to the outer hub and the base at the inner hub. Since the apex region is quite nar-row, the radial height of the disk should be short of the apex or any appreciable thickness in the disk will cause it to contact the spokes. However the disk diameter DM
can be in-creased to nearly that (diameter DOH) of the inner hub by making the disk thin, particu-larly near its outer perimeter 210. Conversely, as will be discussed further below, it is is desirable to maintain the concentration of mass in the disk as far from the center (axis of disk rotation) to attain a high I value for the disk without rendering the disk overly heavy.
In order to accommodate a large-diameter disk, the outer hub 132 has been modi-fied to locate the tire fill stem 220 so as to project from the side of the hub 132, rather than the inner circumferential wall (as shown in phantom). Otherwise, the tire stem may 20 contact the disk or simplysbe rendered difficult to access to fill the tire. A variety of tire stem placements and shape are contemplated and should be within the contemplation of those of ordinary skill whereby interference from the disk can be avoided.

The center of the disk 162 includes a "drive hub" 230 according to an illustrative embodiment. The shape, size and underlying function of the drive hub is highly variable.
25 In this embodiment, the drive hub 230 includes a pull-cord unit that allows the pull-cord to be rapidly paid out by grasping and drawing upon a cord handle 232 that projects from the side of the front wheel assembly. Upon pulling, a ratchet assembly (described further below) engages the disk as causes the disk to spin. The drive hub ratchet works in con-junction with a recoil unit that withdraws the cord after release. The ratchet allows free 30 movement without engaging the disk in the withdrawal direction. It is expressly contem-plated that the drive hub can comprise a variety of mechanisms that initiate a high-rpm spin-up of the disk.

Fig 2A shows a wheel assembly 240 according to an alternate embodiment. As noted above, it is desirable the mass be concentrated along the outer perimeter of the wheel. Those of ordinary skill will recognize that the value for rotational moment of in-ertia (I, which equals mass m times the square of the radius, or I = mr) is optimized where more mass is concentrated at the outer perimeter of a rotating mass.
Accordingly, Fig. 20 shows an embodiment of a rotating mass 250 with spokes, rather than a solid structure. The mass is concentrated in the outer perimeter region 254. In this manner to overall weight of the disk (and hence the front of the bicycle) is reduced without substan-tially reducing I. In further embodiments, the mass can be concentrated in the perimeter of a solid disk by providing special weights (lead or steel billets for example) in an oth-erwise lightened solid disk constructed from, for example, aluminum or composite mate-rials/polymers. Rotating masses need not define a continuous circular perimeter. In al-ternate embodiments, weight can be distributed in the mass at the ends of a plurality of separated arms, so long as the arms or perimeter structure is well balanced with respect to the central axis so as to avoid up-and-down wobble as the mass rotates within a gravita-tional field. For the purposes of this illustration, the first mass 162, shown in Fig. 2 can be constructed of steel with a thickness of approximately one inch (highly variable), a diameter DM of 14 -15.5 inches (highly variable) and an evenly distributed total mass of approximately 13.5 pounds. The example of Fig. 2A the mass 250 is also constructed of steel with a thickness of about 1 inch. It also has an outer diameter DM of approximately 14-15.5 inches. In one experimental implementation, the total mass for this structure is approximately 12.3 pounds (a savings of more than a pound), and the I value is higher than the evenly distributed disk. By using heavier materials in combination with lighter composites the I-to-weight ratio for the mass can be optimized. In one example, the I
value is in a general range of 210 - 240 pounds*in2, but a wider range of values for mo-ment of inertia are expressly contemplated.

Fig. 3 shows a cross section of the central region of a wheel assembly and mass 162 according to the embodiment of Fig. 2. The wheel assembly is mounted on the bot-tom fork ends 140 by a pair of nuts 310, which engage opposing ends of a threaded axle shaft 312. The axle shaft 312 conventionally supports the inner hub 136 on bearings 320.
Note that the structure of the shaft 312 and inner hub 136 is highly variable.
The main object is to provide a wheel that rotates relative to the front fork and a separate rotating mass that rotates freely with respect to both the wheel and the front fork so that the mass can rotate at a relatively high RPM so as to generate a gyroscopic effect even when the front wheel is barely moving or stationary. To accomplish this free rotation of the mov-ing mass, the inner hub136 has been divided into two pieces (or a plurality of sections) 324 and 326 with central break 330 therebetween, over which is placed a cylindrical sleeve 332 that forms a new joint between the separated inner hub sections 324, 326.
This joint maintains the radial alignment of the sections 324, 326 and forms a bearing surface for the mass. The sleeve 332 can be secured to the outside of the hub sections 324, 326 using (for example) welds, fasteners adhesives or a press fit. The outer surface of the sleeve 332 receives a bearing 340 that is pressed into the mass' drive hub 230. The drive hub can be constructed from any durable metal (aluminum alloy, for example) or polymer/composite material. In this manner, the drive hub 320 rotates freely on is bear-ing with respect to the sleeve 332, and hence, the front wheel. The drive hub is secured to the radially outward portion 350 of the mass. This interconnection can be by press fit, fasteners, welds, adhesives or any other acceptable technique. Alternatively, the drive hub 230 and outer mass 350 can be formed unitarily from a single piece of formed, cast, molded, and/or machined material (with appropriate fillers, inserts and weights applied to the material where appropriate).

As shown clearly in Fig. 3, the drive hub includes a cylindrical extension 360 of reduced diameter with respect to the main drive hub portion 366 (that engages the outer mass 350). This extension 360 supports a wrapped cord 362 with a tail end 364 that exits the hub and engages the pull handle 232 shown in Fig. 2 above. The firm withdrawal of the cord causes a rapid spin up of the drive hub. A well-balanced mass with a good bear-ing may spin at high RPM for several minutes. In this embodiment, a spin RPM
of ap-proximately 250-400 RPM is sufficient to provide stability as will be described below.

An optional spacer 370 is provided to at least one side of the sleeve 332.
This spacer assists in maintaining the drive hub axially centered on the sleeve.
Alternate cen-tering and fixing mechanisms are expressly contemplated. In addition, a conical or domed shield 376 is provided between the fork end 140 and spoke flange 370 as shown.
While only one side is shown having a shield, this shield can be applied to both sides of the wheel assembly to protect the rider and others from the fast-rotating mass. The shield can be constructed from a durable polymer, such as polycarbonate. It can be transpar-s ent/translucent and can include various graphics and visual effects where appropriate.
Likewise, the mass can be provided with graphical patterns that, in conjunction with the shield, may be used to create an entertaining effect when in motion. The shield 368 in-cludes a port 380 through which the cord end 364 passes. This allows the user to pull the cord 364 while his or her hands are protected from contact with the mass.

With reference now to Fig. 4, a recoiling, cord-pull drive hub assembly 230 ac-cording to an illustrative embodiment of this invention is shown in further detail. It should be understood that the structure of this assembly is only exemplary.
Those of or-dinary skill should be familiar with this type of rotation-inducing mechanism as it is sub-stantially similar to those found in the pull starters of small engines. The drive hub 230 includes the above-described larger-diameter main portion 366 and a smaller diameter projecting cylinder. This cylinder is actually an outer reel that rotates with respect to the main portion and a fixedly attached inner ratchet base.420. The ratchet base includes a series of radial grooves 430 that selectively engage spring loaded pawls attached to the reel 410 when the cord end 364 is pulled outwardly (arrow 440). That is, the pawls 432 lock into the grooves 430 when the cord is pulled, causing the reel to rotate (curved arrow 444) and the main portion 366 to also rotate (curved arrow 446). However, the reel 410 includes a spring assembly 460 that is unwound by the pulling of the cord, and that re-winds to relieve tension, thereby drawing the cord back into a wound position (dashed arrow 450). The pawls 432 disengage for the ratchet bases 430 in this direction reverse to allow rewind to occur (dashed curved arrow 452). Likewise, the disengaged pawls al-lows the reel to be free from rotation while the mass spins at high speed (thus, no reverse dashed arrow on the main portion 366 is shown).

As noted above, the spin-up mechanism for the mass is widely variable. One al-ternate mechanism is shown in Fig. 5. Simply, the drive hub 510 includes an extension 512 from the main portion 514 that is frustoconical in shape. This allows firm engage-ment with a frustoconical tip 516 of an electrically driven device, such as the illustrated cordless drill 518. The tip can be a hard rubber or other elastomer to firmly engage the extension 512. By simply inserting the drill tip 516 through a hole in the shield (de-scribed above), the tip contacts the extension 512 and spins it once power is applied. In practice, the tip 516 can be provided as part of the kit a user receives with the bicycle 5 and/or accessory wheel assembly of this invention.

Fig. 5A shows a slightly modified drive hub 550 with a main portion 554, in which the same frustoconical tip 516 (as Fig. 5) drives a straight-cylindrical extension 552. The corner 620 of the cylinder may assist in providing engagement between the tip and extension. A variety of tip shapes, extension shapes, materials and surface textures 10 are expressly contemplated.

Having described the structure of an exemplary system for gyroscopically stabi-lizing a front wheel of a bicycle, the function of the system is now described in further detail. Referring to Fig 6, the dynamic forces of interest are as follows:

Rotation of the wheels (curved arrows 610) translates into forward velocity along longitudinal axis 612 (when running with a straightened front wheel). Banking generally about the longitudinal axis (actually about wheel-to-ground contact points) is shown as curved arrow 620. The front wheel steers (curved arrow 630) about the above-described steering axis SA.

The mass 160 rotates about the front wheel axis 650, thereby generating a charac-teristic angular momentum L (where L = Ico, in which (0 is the angular velocity of the rotating mass). The banking rotation represents a torque ti generally about the longitudi-nal axis 612. Where angular momentum and torque cross, a precession is generated.
This precession is the property whereby a gyroscope rotates at a predetermined magni-tude in response to crossed forces. In this case the precession S2P is characterized by the equation:

ti = nP X L.

In other words, the equation governing precession is derived from the fact that torque equals the angular velocity of precession crossed with the angular momentum.
Hence, a torque on a gyroscope (such as the torque from a child falling in an excessive or unintentional bank or tilt about the longitudinal axis) is transferred 90 degrees, and results in precession. For example, if the child were to tip to the right, the wheel would simply turn to the right. This allows the weight of the child to be re-centered over the front wheel. It is particularly desired that precession (S2P) be small in order so as to produce a relatively smooth recovery for the bicycle wheel. Since precession is inversely propor-tional to angular momentum a large Ivalue, produces a relatively small precession for a given applied torque.

Reference is now made to the exemplary rider-training session of Figs. 7-11.
The process begins with the rider 710 seated atop the bicycle 100, grasping the handlebars 124 in forward-steering position, with feet 712 prepared to begin pedaling.
The helper places a grasping hand 720 on the pull-cord handle 232 and rapidly draws it (arrow 722) to spin the mass 160. After spin-up, the rider 710 begins to pedal.

In Fig. 8, the rider 710 experiences and imbalance (arrow 810) that may lead to an unintentional/undesired bank or tilt. This bank occurs in Fig. 9, in which the bicycle leans (arrow 910) over, threatening to eject the rider 710.

As shown in Fig. 10, due to the precession generated by the spinning mass 160, the front wheel 130 turns smoothly (arrow 1010) in the direction of the unintentional bank, causing the handlebars 124 to be firmly urged to "steer-into" the bank.
Thus the rider 710 experiences a turn that causes the bicycle 100 to begin to right itself (arrow 1020). Finally, in Fig. 11, the turn, induced by the imbalance and bank is complete and the rider 710 is riding vertically again in a new direction. The act of banking the bicycle has lead to a conventional turn, without jackknifmg the bicycle or causing it to tip over, thus emulating a natural motion of banking and turning, even at relatively low speeds.
This allows the young, slowly moving rider to learn the dynamics associated with faster riding, while maintaining a slower, safer speed.

To further prove the effectiveness of the stabilizing system of this invention a se-ries of tests were performed with the approximate results shown in Fig. 12. A
bicycle was launched, riderless (e.g. a "ghost" test) along a relatively flat path by hand at a rela-tively slow speed. Data bars for a non-moving mass (1210) show an upright time dura-tion (before falling over) of approximately 1.2 - 2.2 seconds. Results are roughly similar for a bicycle with no mass installed (1220). Conversely, a bicycle with a mass moving at 200-400 RPM (1230) shows markedly increased upright time of approximately 2.3 -seconds, with most times falling into the 4-5 second range (more than double the non-stabilized times).

Similarly, Fig. 13 shows comparative graphs 1310 and 1320, 1330 and 1340 for two respective test subjects, both relatively inexperienced juvenile riders.
The graphs show the length of path traveled versus diversion from a straight path (both in feet). In both cases the graph for the bicycle without spinning mass (1310 and 1330) displays a higher amplitude from a straight line than the graphs for the bicycle with properly spin-ning mass (1320 and 1340).

The foregoing has been a detailed description of illustrative embodiments of the invention. Various modifications and additions can be made without departing from the spirit and scope thereof. By way of example, while a wheel having a plurality of radial thin metal spokes is employed, a variety of wheel and hub structures can be employed.
For example, a hub comprising a pair of clamshell halves that is assembled around the disk can be employed in an alternate embodiment, such a hub cab have outer surfaces that act both as a shield for the disk and the radial load-bearing member between the inner and outer hubs. Similarly, solid spokes with appropriate grooves for nesting the disk can be used. A variety of other improvements and modifications to the wheel, disk or drive hub can be implemented within the spirit and scope of this invention. Finally, while the ex-emplary embodiment described herein has been applied to a bicycle suitable for small children, it is expressly contemplated that this stabilizing system can be applied to the steerable front wheels of a variety of two-wheeled vehicles. In alternate embodiments it can be applied to adult-sized vehicles, and can be continuously powered by electric mo-tor, or the like. This device can alternatively be applied to powered two-wheeled vehi-cles, such as mopeds, motorcycles and scooters to provide further stability and/or act as a training tool. Such an application can be continuously or momentarily powered as ap-propriate. In addition, in alternate embodiments it is expressly contemplated that the ro-tating mass (powered or unpowered) can be provided non-coaxially within the structure of the steerable front wheel. Appropriate mountings and/or spaces can be provided to allow the non-coaxial mass to rotate appropriately free of interference from the moving wheel. Accordingly, this description is meant to be taken only by way of example, and not to otherwise limit the scope of this invention.

What is claimed is:

Claims (12)

1. A system for stabilizing a two-wheeled vehicle comprising:
a moving mass mounted with respect to a steerable front wheel of the vehicle that has a characteristic precession so that the front wheel is urged in a direction of an unin-tentional bank to provide recovery in the form of steering from the bank.

2. The system as set forth in claim 1 wherein the moving mass comprises a disk mounted on a bearing structure coaxial with an inner hub of the front wheel.

3. The system as set forth in claim 2 wherein the front wheel is a bicycle front wheel mounted on a steerable fork operatively connected to handlebars.

4. The system as set forth in claim 3 wherein the disk comprises a structure having mass concentrated adjacent to an outer perimeter thereof.

5. The system as set forth in claim 3 wherein the mass includes a drive hub located adjacent to the inner hub and including an interface adapted to cause the mass to freely spin at for a desired time interval about the inner hub.

6. The system as set forth in claim 5 wherein the drive hub includes a pull cord that spins the hub by action of pulling and a recoil winding reel to draw the cord after pulling.

7. The system as set forth in claim 5 wherein the drive hub is constructed and ar-ranged to engage an electrically operated tip that causes the drive hub to spin in response to engagement by and rotation of the tip.

8. The system as set forth in claim 1 wherein the front wheel includes a shield that restricts access to the mass.

9. The system as set forth in claim 8 wherein the shield includes a port through which a mechanism that spins the mass is passed.

10. A method for stabilizing a two wheeled vehicle, at least during start of vehicle motion comprising the steps of:
initiating rotation of a rotating mass mounted with respect to a steerable front wheel of the vehicle;
while mounted on the vehicle, initiating forward motion using a mechanism that rotates a rear wheel of the vehicle; and responding to precession induced in the front wheel by motion so as to reduce un-intended tilting of the vehicle.

11. The method as set forth in claim 10 wherein the step of initiating rotation com-prises applying to the rotating mass, and then withdrawing from the rotating mass, a ro-tating, electrically operated mechanism.

12. The method as set forth in claim 10 wherein the step of initiating rotation com-prises causing the rotating mass to rotate on a mounting coaxial with an axle of the front wheel that allows the rotating mass to freewheel with respect to the front wheel.