JP3665332B2 - Wheel vehicle - Google Patents

Description

The present invention relates to a wheel vehicle.
Wheel vehicles such as motor skate typically used for entertainment are described in, for example, FR 26 25 688 Al and DE 32 05 379 Al. The vehicle shown herein includes a board, and the board is provided with two wheels that are rotatably mounted in series under the board or in an opening of the board. The person who uses this skate (board) steers the board by standing and moving his / her weight on the board. The disadvantage of such a design is that it is very difficult or impossible to use this motor skateboard in rough terrain, due to the small wheel size and the wheel bearing arrangement with respect to the board. It is to become.
In accordance with the present invention, a wheel vehicle for carrying a person is provided,Along the vertical axis indicating the direction of travel when using a wheel vehicleSubstantially in seriesArranged inA frame for rotatably supporting two wheels and a foot support means for supporting a user's foot in use, the wheel being annular, the foot support means being coupled to the frame and passing through each wheelWheelExtending in the axial direction,Includes spaced platform structures.
The present invention also providesA wheel vehicle,
Frame,
Two annular wheels supported by a frame and arranged substantially in series along a longitudinal axis indicating the direction of travel when using the wheel vehicle;
An inner wheel support means coupled to the frame for rotatably supporting the inner rim portion of the wheel;
A wheel vehicle is provided that includes a foot support member coupled to the frame and extending through the annular wheel.
The present invention is also a wheel vehicle for carrying a person,
Frame,
An annular wheel mounted on the frame and arranged around the annular wheel and rotatably supported by the frame by a plurality of rollers supporting the inner circumferential surface of the wheel;
Further load bearing means coupled to the frame and associated with the wheel to support the frame in a horizontal plane on which the wheel vehicle rides;
A foot support member coupled to the frame, at least one of which provides a wheel vehicle for carrying a person extending through an annular wheel.
PreferablyThe further load bearing means includes an annular wheel rotatably supported in a frame by a plurality of rollers, wherein the vehicle is arranged substantially in series along a longitudinal axis that indicates a direction of travel during use of the wheel vehicle. Including two annular wheels.
Preferably,The further load bearing means includes a ski or skid member disposed substantially in series with the wheel along a longitudinal axis that indicates the direction of travel during use of the wheel vehicle.
Preferably, the foot support member includes a platform structure coupled to the frame and extending axially through each wheel to allow a person to stand thereon.
Preferably, the wheel vehicle includes a motor mounted and coupled to the frame to drive the wheel or one of the wheels rotatably.
Preferably, throttle control means operable by a human hand standing on the foot support member is connected to the motor.
Preferably, the frame is joined between two wheels, allowing the vehicle to be steered in use by a pivoting movement with respect to one of the wheels.
The present invention further includes a frame on which a drive engine is mounted,
It is supported rotatably by the frameMultipleWith wheels,
Transmission means for transmitting drive torque from the drive engine to the wheels;
Foot support means that people can step on while the vehicle is moving;
Control means that can be operated by a person standing on the foot support means to adjust the drive engine,
The wheels are annular and each annular wheel is rotatably supported at different angular positions by at least three support rollers engaging its inner circumferential surface, and the bearing shafts of the support rollers are fixed to the frame. The foot support means are each through one of the annular wheels.WheelA motor vehicle is provided that includes two foot platforms extending axially.
The three rollers are preferably arranged symmetrically around the or each wheel and support the inner circumferential surface of the wheel, but in one embodiment four rollers are provided to support each annular wheel. Two of the rollers are in a substantially common horizontal plane with the upper surface of each foot platform, and the other two rollers of each wheel are positioned directly above and below the foot platform, respectively.
Preferably, also, the two wheels are arranged substantially in series with a drive engine mounted on the frame between them, the frame being divided into two parts, each part having one of the wheels. .
Alternatively, only one wheel may be provided, or multiple wheels may be provided that can rotate about the same axis. In such cases, skis, slides, skids or similar non-rotating support members may also be provided that are substantially in series with the wheel or wheels.
The motor vehicle according to one embodiment of the present invention has a low center of weight for the suspension of individual foot platforms extending through the annular front and rear wheels due to the suspension or bearing of the annular wheel by the respective support rollers of the frame. It can be operated in rough terrain.
The present invention further provides a steering mechanism for coupling the wheel to the vehicle, including a first pivot connection and coupling member between the vehicle and a structure that rotatably supports the wheel, the coupling member comprising: A second pivot connection between the coupling member and a third pivot connection between the coupling member and its structure, the second and third pivot connections being spaced apart from each other along the direction of travel of the vehicle in use. Between the axes passing through the first turning connection and the second and third turning connections, respectively, because the second and third turning connections are opposite to the first turning connection with respect to the rotation axis of the wheel. The wheel turns with respect to the vehicle with respect to the turning axis which is variable at.
The present invention will be described in further detail hereinbelow by way of example only with reference to the accompanying drawings.
FIG. 1 is a schematic side view of a motor skate vehicle according to a first embodiment of the present invention.
FIG. 2 is a schematic view of the skate vehicle shown in FIG.
3 and 4 are opposing side views of a wheel vehicle according to a second embodiment of the present invention.
FIGS. 5 and 6 are top and bottom views of the wheel vehicle of FIGS. 3 and 4, respectively.
The motor skate vehicle shown in the drawing is intended to be used in a manner similar to that by a person standing free on a motor skateboard, but has significant advantages and will be clear from the following description Will. The vehicle shown in FIGS. 1 and 2 includes a frame structure having a rear frame portion 10 and a front frame portion 12. The front frame portion 12 is pivotally connected to the rear frame portion 10 and allows a limited swivel movement along a swivel axis A that is substantially perpendicular to the horizontal plane B.
The upper end of the front frame part 12 is provided with two connection plates 14 arranged in parallel to each other and extending substantially horizontally, between which the short connection tube 16 of the rear frame part 10 is provided. Inserted and held in place to rotate by bolts 18 passing through the respective bores of the connecting plate 14 and the axial bore of the connecting tube 16. The bolt 18 is tightened to oppose axial movement within the connecting tube 16, resulting in a hinge-like arrangement.
The front frame portion 12 is at a lower location and has a foot platform 121 that looks like a very large sole and extends horizontally across the longitudinal axis C. Foot platform 121 is lightweight and is shaped and designed to withstand significant bending movements when using a vehicle. The front frame portion 12 further includes a shin rest 125 that extends vertically upward from the foot platform 121 and is integrally formed in the form of a foot insert, such as an open boot in the rear portion. The connecting plate 14 is formed integrally with or fixed to the upper portion of the shin pad 125.
The rear frame portion 10 is composed of two slightly curved tubular members 19 and 20 whose front ends are attached to a connecting tube 16 extending substantially perpendicular to them. Tubular members 19 and 20 extend rearwardly from connecting tube 16 and slightly diverge from each other in the vertical direction. Viewed from above, the members 19, 20 are curved with respect to the longitudinal axis C so that the front portions of the tubular members 19, 20 are along the axis C and the rear portions are offset.
The rear ends of the tubular members 19, 20 lead to or are connected to a generally circular tubular portion 22 having a horizontal portion 23 straightened or flattened at the lower portion. As can be seen from FIG. 2, the circular tubular portion 22 is arranged so that the vertical plane is not curved and is parallel to the longitudinal axis C.
The rear frame portion 10 also has a foot platform 101 formed in the same manner as described above and provided with a shin pad 105 that is integrally formed or attached. The foot platform 101 is securely fixed to the straight portion 23 of the circular tubular portion 22, while the shin plate 105 is securely attached to the curved portion 22 facing the straight portion 23 by any suitable means such as a screw or bolt. Fixed. The rear frame tubular members 19, 20, portion 22, attached foot platform 101, and shin pad 105 provide efficient lateral, vertical, horizontal and diagonal stiffness, leaving flexibility It is designed to enhance the stability of the entire frame portion 10 itself. The same applies to the previous frame portion 12.
The frame portions 10, 12 can be formed from, for example, aluminum or a light alloy, or a fiber reinforced plastic or carbon reinforced phenol, or a combination thereof. This also means that, for example, the rear frame portion 12 is formed from welded tubular aluminum struts, a foot plate with an integrated shin plate and a suitable plastic capable of reinforcing the entire front frame portion 10. It means that materials can be used and can be integrally molded.
The skate vehicle has two annular main wheels 30, 32 arranged in series along the longitudinal axis C for rotation about an axis across the axis C.
In this embodiment of the invention, each annular wheel 30, 32 has an annular rim 34 with an inner circumferential surface 36 having a profile with a portion 36a projecting inwardly. The outer peripheral surface is preferably formed to securely receive an inflatable rubber tire 38 with a tread profile suitable for use on rough terrain. In one embodiment, not shown, the annular wheel can be integrally formed in one piece using a rigid or semi-elastic plastic material that can withstand proper polishing. The rim 34 may be formed from, for example, aluminum or another light alloy, or reinforced plastic, ie PA66.
The front and rear annular wheels 30, 32 are respectively held in rotation by the front frame portion 12 and the rear frame portion 10 by a set of three support roller 40 openings, each set of rollers being Arranged at the corners of an imaginary equilateral triangle and engaged with the inner circumferential surface 36 of each annular wheel 30, 32. The contour of the outer peripheral surface 42 of each roller correlates with the inner peripheral surface 36 of the rim 34, that is, includes an inclined lateral portion between which a peripheral recess is formed to receive the protruding portion of the rim 36. . This is illustrated in FIG. With this arrangement, the engagement of the roller 40 at the rim 34 is positive and reduced in friction, and the wheel-roller arrangement allows the annular wheels 30, 32 to be displaced in a substantial lateral direction without deviating from each of the three support rollers 40. It is possible to withstand the power of
Each support roller 40 is held for rotation by a bearing shaft or bolt 44 held stationary at the respective frame portion 10, 12. The front frame portion 12 has bifurcated extensions 123, 124 on the front and rear sides of the foot platform 121, and between them, as can be seen from the cut out portion of FIG. Each support roller 40 is supported by means of each bearing shaft 44 extending in the axial direction.
The extending portions 123 and 124 are slightly curved upward, but the surface on which the foot platform 121 extends is substantially the same surface as the horizontal surface on which the two support rollers 40 are disposed. A bearing shaft or bolt 44 for the third support roller 40 of the front frame portion 12 extends to the annular wheel 32 before traversing the vehicle and is attached to the shin pad 125 or formed integrally with the shin pad 125. It is mounted in a support (not shown) such as a bracket.
Similarly, three support rollers 40 are attached to the rear frame portion 10 with a circular tubular portion 22, two of the support rollers 40 are located at the front and back ends of the straight tubular portion 23, The third support 40 is attached to the upper part of the circle. The circular tubular portion 22 is reinforced in the area that supports the respective bearing shaft or bolt 44 to the support roller 40 to prevent the bearing bore from being damaged due to wear.
As can be seen from the drawing, the shin rest generally juxtaposes on each side of the wheels 30, 32 on the same side of the vehicle, leaving sufficient clearance for the wheels 30, 32 to interfere and rotate freely. The foot platforms 101 and 121 traverse the central plane of the wheels in a manner that extends upward in configuration and a boot-like cover of the foot platforms 101, 121 passes through the wheels 30, 32 and projects laterally therefrom. Extending through respective front and rear wheels 30,32. The foot platforms 101 and 121 are respectively positioned between the two lower support rollers 40, and the lower support rollers are disposed at the front and rear ends in each case. The foot platform is so arranged with respect to the longitudinal axis C so that the weight distribution at each support roller 40 is optimal and the bending moment along and perpendicular to the C axis is minimized.
The skate vehicle is further provided with, for example, a combustion or electric type drive engine 50 that is securely attached to the rear frame portion 10 and arranged to reduce the rotational moment about the longitudinal axis C due to the asymmetric weight distribution.
The drive engine 50 may be the same as that used in a domestic mower. The drive engine 50 (directly or by an intermediate reduction gear) is fixed to the rim so as to rotate with the drive pulley 57 on the drive engine side and the rim 34 of the rear wheel 30 in this embodiment. The rear wheel 30 is driven through suitable transmission means 55 comprising a drive ring 58. An endless drive belt 59 that moves on the pulley 57 and the ring 58 is provided to transmit torque from the drive engine 50 to the rear wheel 30. Engagement between the endless drive belt 59, pulley 57 and ring 58 can be of a simple frictional nature or achieved with a toothed endless belt with a corresponding toothed pulley and ring. can do.
One embodiment, not shown, uses a friction roller that is directly connected to the drive engine or reduction gear and engages the rear wheel, preferably in the same manner as the engagement described above in connection with the support roller and wheel. Torque transmission can alternatively be achieved to the inner circumferential surface. In order to operate the drive engine 50 and adjust its power output, a multi-purpose handle 60 having a swivel lever 61 and adjusting the rotation of the drive engine is provided in this embodiment. The multipurpose handle 60 is connected to the drive engine 50 by a suitable flexible connection line 62. The skate vehicle is provided with a small gasoline tank or battery for the drive engine 50 (not shown). Known types of brakes, such as those used for bicycles, are incorporated into the skate vehicle, and one or both wheels 30, 32 can be braked and operated from the multipurpose handle 60.
The flexible connection line 62 has an outer tubular cover that includes a longitudinally extending slidable flexible member that moves longitudinally within the cover upon actuation of a pivoting lever 61 of the handle 60 to provide a vehicle. For example, a throttle movement for the motor may be enabled. In the case of an electrically energized vehicle, this movement may control the circuit for the motor. In either case, the motor is controlled by an electrical signal carried by one or more wires forming line 62 or by carrying a pneumatic or hydraulic signal through the line, in this case formed as a flexible duct. The line 62 can be arranged as follows.
Referring to FIGS. 3-6, there is shown a wheel vehicle 200 that operates similarly to the motor skate vehicle described above, but employs a slightly different configuration. Front and rear annular wheels 206, 204 are provided, each having an open central portion, the circumference of which is defined by the wheel bearing rim 208. The outer circumferential portion of each of the annular wheels 206, 204 is advantageously provided with an all-terrain tire with a suitable tread such as an inflatable rubber tire. Annular wheels are actually composed of wheels intended for use on small motorcycles with the hub and spokes removed and the inner central part defined by the wheel bearing rim 208 open. May be. The outer shape of such a wheel may be on the order of 40 cm, for example.
The main structure of the vehicle 200 is provided by the front and rear chassis portions 220, 218, the lower chassis portion 222, and the chassis bar 250. The rear chassis 218 is integrally formed with the lower chassis 222 and is made of a molded elastic hard material such as glass reinforced plastic. The rear chassis 218 is shaped to substantially cover one side of the rear annular wheel 204 and its upper portion in the form of a mudguard. A portion of the rear chassis 218 is recessed to extend through the open center portion of the rear wheel 204 to form a rear foot cover 216, the lower portion of which is a semi-circular upper foot. It includes a rear foot platform that also extends laterally and in the opposite direction to the recess. A laterally extending rear foot platform 254 also extends centrally between the front and rear wheels 206, 204 to provide a mounting surface for the engine 236 and a lower chassis 222 including an extension of the rear foot platform 254, and It is formed integrally.
The front chassis 220 is constructed in the same manner as the rear chassis 218 and extends laterally from the face of the front wheel 206 and extends through its open central portion in the form of a front foot cover 217. A platform 256 is provided.
The front and rear annular wheels 206, 204 are respectively mounted for rotation on the front and rear chassis portions 220, 218 by means of bearing rollers 210. As best shown in FIG. 3 for the rear annular wheel 204 and the rear chassis 218, four bearing rollers 210 are provided at spaced locations around the inner circumference of the wheel 204. It is done. Since the bearing rollers 210 are fixed with respect to the vehicle frame and each support a bearing rim 208 of the wheel, the wheel undergoes rotational movement with respect to the frame. A roller frame 212 is mounted on the rear chassis 218 under the rear foot platform 254 and foot cover 216 and generally comprises Y bearing rollers 210b, 210c and 210d mounted for rotation at the ends of the arms of the frame. It has a shape. The bearing rollers 210b and 210c are positioned on one side of the rear foot cover 216 extending through the rear annular wheel 204 and the bearing roller 210d is a circle inside the rear wheel 204 directly below the rear foot platform 254. Support the lap. The upper bearing roller 210 a is provided directly above the rear foot cover 216 and is attached to the upper portion of the rear chassis 218. Further support for the rear bearing roller 210a may be provided by an upper roller support 214 extending from the top of the rear foot cover 216. In order to allow the wheel to withstand lateral forces without leaving the bearing roller 210, each bearing roller is raised on the inner circumference of the wheel rim 208 of the wheel 204, 206 wheel. A central circumferential groove is provided that cooperates with the part. With this arrangement, the lateral force applied to the wheels 204, 206 is passed through the circumferential raised portion on the inside of the wheel to the circumferential raised portion defining the central groove of the bearing roller 210, and thus the front Or it can be communicated to the rear chassis 220, 218.
The wheel vehicle 200 further includes an engine 236 mounted on the lower chassis 222 in series between the front and rear annular wheels 206, 204. Preferably the engine comprises a single or multi-cylinder gasoline fuel engine, often utilized in motorized horticultural equipment, advantageously of the air-cooled type. The engine 236 is arranged with a rotary drive shaft having a rotation axis parallel to the axis of the rear annular wheel 204. An engine drive sprocket 238 is coupled to the engine drive shaft and supports the gear chain 240 to drive the gear sprocket 242. The gear sprocket 242 is rotated between the engine drive sprocket 238 of the rear annular wheel 204 by means of a mounting plate coupled between the lower front part of the rear chassis 218 and the lower chassis 222. It is attached to. A further sprocket (not shown) is mounted to rotate coaxially with 242 to a gear sprocket arranged to transmit torque to the rear annular wheel 204 by means of a drive chain 246. To this end, the rear annular wheel 204 is provided with a wheel sprocket 248 that is proximate to and coaxial with the wheel bearing rim 208 and mounted on the side of the rear wheel 204. To provide the necessary gear reduction from the engine 236 to the rear wheel 204, the size or number of gear teeth applied to the gear sprocket 242 is larger than that of the engine drive sprocket 238, and similarly the wheel sprocket 248 , Much larger than a further sprocket (not shown) driven from it. In use, the engine 236 may be controlled by means of a control handle 237 that incorporates a throttle control lever 239 that is coupled to the throttle mechanism of the engine 236 by a flexible control cable 235. A brake mechanism may be applied to the front and / or rear annular wheels 206, 204 using the corresponding brake actuation mechanism of the control handle 237, but in this embodiment, while the throttle is fully closed Engine 236 has been found to provide sufficient braking torque.
The upper portion of the rear chassis 218 and the front portion of the lower chassis 222 to increase the structural stability of the rear chassis 218 and the lower chassis 222 and to provide a means for coupling the front chassis 220 thereto And a chassis bar 250 is provided that passes between and in front of the engine 236. The front chassis 220 and the front annular wheel 206 are coupled to the vehicle 200 by means of a swivel arm 224 and a steering link bar 228. As best seen in FIGS. 5 and 6, the pivot arm 224 is angled laterally forward from the front end of the lower chassis 222 to a fixed elbow joint, with the pivot arm 224 in the front An angled member that is angled inwardly from an elbow joint fixed to the lower steering pivot 226 that connects to the roller frame 212. The front chassis is also connected to pivot to the front chassis 220 by means of the front upper steering pivot 232 and is connected to pivot to the chassis bar 250 by means of the rear upper steering pivot 230. The link bar 228 is coupled to the chassis bar 250. A steering bias spring 234 also couples the front chassis 220 to the chassis bar 250 at the rear upper steering pivot 230 and the connection of the steering bias spring to the front chassis 220 is behind the front upper steering pivot 232. . The lower steering pivot 226 advantageously has more than two dimensions such as a ball tube joint that allows the front chassis 220, front wheel 206 and steering link bar 228 to pivot on both the front and rear upper steering pivots 232, 230. It can turn. With reference to FIG. 3, this allows the front annular wheel 206 to pivot anywhere between axes X and Y through the lower steering pivot 226 and the rear and front upper steering pivots 232, 230, respectively. Can be rotated around. The lower steering pivot 226 is positioned with the front roller frame 212 in the forward direction of the rotational axis of the front annular wheel 206, while the front upper steering pivot 232 is positioned slightly behind the rotational axis, while the chassis bar 250 The rear upper steering pivot 230 is far behind the front wheel axis of rotation. Further, since the steering bias spring 234 is coupled to the front chassis 220 near the upper steering pivot 230 behind the front upper steering pivot 232, the front chassis 220 is caused by the elastic action of the spring 234. , Biased against rotation about the front upper steering pivot 232. Such an arrangement of the pivots 230, 232, 226 and the bias spring 234 creates a steering mechanism that is fast, stable and steerable at low speeds thanks to the adjustable pivot shaft and spring bias. The elbow joint protruding and fixed to the side of the pivot arm 224 forms a space in which the front wheel 206 and the front chassis 220 can turn within the range of the pivot arm 224. Although the illustrated configuration has been described with a lower steering pivot 226 positioned in front of the front wheel axis of rotation, this is not necessarily required to achieve the benefits of the steering mechanism. Depending on the desired maneuvering characteristics, the position of the lower maneuvering pivot 226 is actually changed along the front roller frame 212 so that it is positioned behind or in front of the front wheel axis of rotation. Also good. With the pivot 226 positioned in front of the roller frame 212, the vehicle tends to be poorly handled in handling characteristics, whereas with the pivot 226 positioned behind, over-steering characteristics can be achieved.
This steering mechanism is very different from the conventional wheel vehicle steering mechanism in which the head stem bracket is provided on the frame and the front wheel and, in the case of a bicycle or motorcycle, a shaft coupled to a device such as a handlebar is restricted in turning. First, since the majority of the load on the vehicle is efficiently transmitted to the front and rear annular wheels 204, 206, the steering mechanism has a large amount of force related to the load between the front and rear chassis portions 220, 218. There is no need to communicate. Furthermore, the steering mechanism of the wheeled vehicle 200 does not need to be coupled to a central member of the front wheel 206, such as a central accelerator, thus providing great flexibility in the placement of turning points in the steering mechanism.
In using the wheeled vehicle 200, the user stands on the vehicle with the left foot on the front foot platform 256 and the right foot on the back foot platform 254 facing the direction shown in FIG. The user's feet pass through the front and rear annular wheels 206, 204 and protrude into the front and rear foot cover recesses 217, 216. The rider grips the control handle 237 with one hand, thereby adjusting the engine throttle and operating the vehicle. It is also possible to maneuver the vehicle at low speed by manipulating the front chassis 220 and front wheel 206 with the left foot and maneuvering the vehicle by manually rotating the front annular wheel 206 around the steering pivot. The structure of the vehicle 200 is such that the foot platform 254, 256 protrudes through the central portion of the annular wheels 204, 206 so that the vehicle combines a low center of weight with a relatively large wheel, while A short wheel base can be maintained. Stability is improved by transmitting the rider's weight to the vehicle through the rider's feet placed just above the point where the vehicle wheels 204, 206 are in contact with the ground.
In summary, the annular wheels are arranged in series with each other, are held to rotate on the inner circumferential surface by support rollers arranged around the inner circumference, and are rotated by the frame structure. And two individual footrests or platforms can be provided to extend across the vehicle through each of the annular wheels, and by virtue of the bearing arrangement of such annular wheels, the vehicle It has the advantage of a low center. In this way, a person can “ride” the vehicle in the same way as with a surfboard, i.e., standing freely with the body facing sideways in the direction of travel, balancing the vehicle by moving the body, The vehicle can be steered by turning the front wheel using the foot of the vehicle or by moving the weight from the center of weight in a conventional manner. However, a handlebar may be provided to increase stability. Therefore, it is not strictly necessary to provide a two-part frame having a front wheel capable of turning, and in another embodiment of the present invention, the frame can be configured as one, so that the actual frame configuration As such, various designs are possible. Similarly, it is not strictly necessary to have a tubular frame portion, and a plate-like integrated body frame is also possible. In another embodiment, the front wheels can be replaced with elements such as skis or skates so that the skate vehicle can be used on snow. The use of this vehicle in rough terrain can further increase the range of use when using larger diameter annular wheels when compared to conventional skateboards or scooters. Further, the embodiments of the present invention described herein utilize rollers that are secured to a frame that supports an annular wheel, but that extends around each foot platform, and includes a hub and a corresponding inner wheel. A circular hub defining an annular space between the circumferential surface is provided in the frame, and the hub itself is fixed with respect to the frame so that the bearing roller is between the hub and the circumferential surface inside the wheel, The wheels can be rotated without the bearing rollers moving in the annular space and constraining the hub.
In a further embodiment, the vehicle frame is flexible, in which case the front and rear frame portions generally allow for hinged movements between the front and rear portions around an upright axis. Interconnected by the elastic parts of the frame. This allows the vehicle to “walk” under user control. Elasticity can be provided by forming the frame, or at least the portion joining the front and back portions, as an inflatable structure.
The foregoing detailed description of the present invention has been presented for purposes of illustration only and is not intended to limit the invention as defined by the appended claims.

Claims (11)

A wheel vehicle for carrying a person, the frame rotatably supporting two wheels arranged substantially in series along a longitudinal axis indicating a traveling direction when the wheel vehicle is used, and a user when using the wheel vehicle wherein the a foot support means for supporting the foot, the wheel is annular, foot support means is coupled to said frame and extending in the axial direction of the wheel through the wheel, respectively, the spacing provided Wheel vehicle, including platform structure. A wheel vehicle,
Frame,
Two annular wheels that are supported by a frame and arranged substantially in series along a longitudinal axis that indicates the direction of travel in use of the wheel vehicle ;
An inner wheel support means coupled to the frame for rotatably supporting the inner rim portion of the wheel;
A wheel vehicle including a foot support member coupled to the frame and extending through the annular wheel. A wheel vehicle for carrying people,
Frame,
An annular wheel mounted on the frame and arranged around the annular wheel and rotatably supported by the frame by a plurality of rollers supporting the inner circumferential surface of the wheel;
Coupled to the frame, in connection with the wheels, and further the load bearing means adapted to support the frame in the horizontal plane ride of the wheel vehicle,
A wheel vehicle for carrying a person, including a foot support member coupled to the frame, at least one of which extends through an annular wheel. The further load bearing means includes an annular wheel rotatably supported in a frame by a plurality of rollers, and the vehicle is disposed substantially in series along a longitudinal axis that indicates a direction of travel during use of the wheel vehicle. 4. The wheel vehicle of claim 3, comprising only two annular wheels. 4. A wheel vehicle as claimed in claim 3, wherein the further load bearing means comprises a ski or skid member arranged substantially in series with the wheel along a longitudinal axis indicating the direction of travel during use of the wheel vehicle. The wheel vehicle of claim 4, wherein the foot support member includes a platform structure coupled to the frame and extending axially through each of the wheels to allow a person to stand thereon. The wheel vehicle according to claim 1 or 2, comprising a motor mounted to and coupled to the frame to drive one of the wheels rotatably. The wheel vehicle according to claim 3, comprising a motor mounted on and coupled to the frame to drive the wheel rotatably. The motor is operable throttle control means by the hand of a person standing on the foot support member is connected, the wheel vehicle according to claim 7 or 8. 5. A wheel vehicle according to claim 1, 2 or 4, wherein the frame is joined between two wheels and allows the vehicle to be steered in use by a pivoting movement with respect to the other of the one wheel. A motor vehicle,
A frame on which the drive engine is mounted;
A plurality of wheels rotatably supported by the frame;
Transmission means for transmitting drive torque from the drive engine to the wheels;
Foot support means that people can step on while the vehicle is moving;
Control means by which a person standing on the foot support means can operate to adjust the drive engine,
The wheels are annular, and each of the annular wheels is rotatably supported at different angular positions by at least three support rollers engaged with the inner circumferential surface thereof, and the bearing shaft of the support roller is fixed to the frame Wherein the foot support means includes two foot platforms each extending in the axial direction of the wheel through a respective one of the annular wheels.

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