The illustrative embodiments relate to a vehicle with a two-section chassis, the ability to move in multiple orientations and execute movements including a side rollover movement where a pivot mechanism assists in directing the vehicle to roll over between a first orientation and a second orientation.
Remote control vehicles have long been known in the art and commonly used by children and adults for a variety of entertainment activities. Examples of vehicles include cars, trucks, aircraft, and watercraft. A continuing need exists for new performance features to add entertainment and play value to remote controlled vehicles.
In one or more illustrative embodiments there may be provided a toy vehicle having a two section chassis including a first section and a second section pivotally attached to one another, the first section further defined as a leading section relative to the direction of vehicle movement, the second section further defined as a trailing section relative to the direction of vehicle movement; two sets of wheels, a first set and a second set rotatably attached to their respective sections where each wheel includes an edge and a height greater than the height of the two section chassis. The vehicle may further include a first orientation and a second orientation, the second orientation further defined as a vehicle orientation opposite the first orientation; a center of gravity defined by the vehicle and a power source in communication with a motorized capability to steer and direct vehicle movements; and the motorized capability to steer and direct vehicle movements in communication with at least one of the wheels and configured to drive the vehicle through movements including a rollover movement. The rollover movement is a movement where the vehicle rolls over between the orientations when the vehicle is at rollover speed and in a rollover alignment. During the rollover movement the vehicle may roll between the first orientation and the second orientation further defined to include the vehicle rolling over from the first orientation to the second orientation or the second orientation to the first orientation. The rollover speed is further defined as a speed at which friction between a surface and one of the leading section wheel edges creates a frictional pivot point when in the rollover alignment. The rollover alignment is further defined as an angled pivotal alignment between the sections such that the vehicle's momentum at rollover speed and the center of gravity cause the vehicle to roll over about a central vehicle axis and over the frictional pivot point. The rollover movement may be triggered by a variety of occurrences such as when the vehicle is at rollover speed and an external force triggers the rollover alignment. The two sections may additionally have a bumper extending past the respective set of wheels.
In another illustrative embodiment there may be provided a toy vehicle having a two section chassis with a pivot mechanism rotatably attaching the two sections where the first section is further defined as a leading section relative to the direction of vehicle movement and the second section is further defined as a trailing section relative to the direction of movement. The vehicle may further include four wheels with a height greater than a height of the chassis and an edge; two of the four wheels are rotatably attached to the first section and the other two wheels are rotatably attached to the second section; a first orientation and a second orientation which is opposite the first orientation; and a center of gravity defined by the vehicle. The vehicle may also include a drive motor and a pivot motor, the drive motor in communication with at least one of the four wheels such that the drive motor is configured to drive forward and reverse movement of the vehicle and the pivot motor is in communication with the pivot mechanism such that the pivot motor is configured to drive rotation of the pivot mechanism. A control system with an integrated circuit and programmed software instructions may be included in the vehicle. The integrated circuit is in communication with the drive motor and pivot motor and the control system is configured to steer and direct the vehicle through movements. A power source is in communication with the drive motor, pivot motor, and control system. One of the vehicle movements is a rollover movement where the vehicle rolls between the first orientation and second orientation when the vehicle is at a rollover speed and in a rollover alignment. The rollover speed is further defined as a speed at which friction between a surface and one of the leading section wheel edges creates a frictional pivot point when in the rollover alignment; and the rollover alignment is further defined as an angled pivotal alignment between the two sections such that the vehicle's momentum at rollover speed and center of gravity cause the vehicle to roll over about a central vehicle axis and over the frictional pivot point. The vehicle may further include a capability for activating the programmed software instructions which may be configured to activate and control the drive motor to move the vehicle, and further configured to activate and control the pivot motor to rotate the pivot mechanism to steer the vehicle. Additionally, the software instructions may be configured to move the vehicle in a first direction such that the vehicle reaches rollover speed, and further configured to rotate the pivot mechanism to turn the lead section to the rollover alignment to create the frictional pivot point between the surface and the leading section wheel edge such that the vehicle rolls over between the first orientation and the second orientation, thereby completing the rollover movement.
In yet another illustrative embodiment there may be provided a toy vehicle having a first section and a second section with a pivot mechanism rotatably attaching the two sections such that the sections rotate substantially freely relative to one another. The first section is further defined as a leading section relative to the direction of vehicle movement and the second section is further defined as a trailing section relative to the direction of movement. Four wheels are rotatably attached to the vehicle including two drive wheels and two free wheels, each wheel including an edge and a height greater than the height of the two section chassis. The vehicle further includes a first orientation and a second orientation opposite the first orientation; a center of gravity defined by the vehicle; two drive motors, each in communication with one of the two drive wheels such that each drive motor is configured to drive forward and reverse rotation of the respective drive wheel; and a control system. The control system may have an integrated circuit in communication with the two drive motors and having programmed software instructions stored therein. The control system is configured to steer and direct the vehicle through movements including a rollover movement. A power source is in communication with the two drive motors and the control system. One of the movements is a rollover movement triggered when the vehicle is at a rollover speed further defined as a speed at which friction between a surface and one of the leading section wheel edges creates a frictional pivot point when the leading section rotates far enough to the left or right such that the vehicle's momentum and center of gravity cause the vehicle to roll over between the first orientation and the second orientation about a central vehicle axis and over the frictional pivot point. The vehicle may further include a capability for activating the programmed software instructions configured to activate and control the drive motors to move and steer the vehicle. Additionally, the software instructions may be configured to move the vehicle in a first direction such that the vehicle reaches rollover speed, and further configured to direct enough power to one of the drive motors to turn the first section to create the frictional pivot point between the surface and one of the leading wheel edges to roll the vehicle between the first orientation and the second orientation to complete the rollover movement.
The vehicle may also include a capability to align the two sections in a substantially linear relationship following an angled alignment between the sections. The capability to align the two sections in a substantially linear relationship may comprise the pivot mechanism including a pair of flanges extending from one of the sections and an extension extending from the other section. A first magnet is positioned on one of the flanges and a second magnet is positioned on the extension such that the polarities of the magnets attract one another. Wherein the magnets include a level of magnetism to suppress rotation of the pivot mechanism while assisting in returning the two sections to the substantially linear alignment following vehicle turning movements.
Numerous other advantages and features of the invention will become readily apparent from the following detailed description of the embodiments thereof, from the claims, and from the accompanying drawings.
A fuller understanding of the foregoing may be had by reference to the accompanying drawings, wherein:
a is a top view of an illustrative embodiment of a vehicle;
b is a top view of the vehicle from
c is a front view of another illustrative embodiment of a vehicle illustrating a modified set of wheels in comparison to a typical wheel set;
d is front view of a modified wheel profile compared to the geometry of a sphere or circle;
a is a front perspective view of another illustrative embodiment of a vehicle in a first orientation;
b is a front perspective view of the vehicle in
c is a front perspective view of the vehicle from
d is a front perspective view of the vehicle from
a is a top view of
b is a top view of the vehicle from
c is a top view of the vehicle from
d is an enlarged side view of the vehicle from
e is an enlarged perspective view of the vehicle from
f is a front view of an exemplary wheel utilized in one embodiment of the present invention;
a is a front view of the vehicle from
b is a front view of the vehicle from
c is a perspective view of the vehicle from
d is a perspective view of the vehicle from
e is a perspective view of the vehicle from
f is a perspective view of the vehicle from
g is a perspective view of the vehicle from
h is a side view of the vehicle in the second orientation from
a is a top view of the vehicle from
b is a perspective view of the vehicle from
c is a perspective view of the vehicle from
d is a perspective view of the vehicle from
e is a perspective view of the vehicle from
f is a perspective view of the vehicle from
g is a top view of the vehicle in the second orientation from
a is a front perspective view of another illustrative embodiment of a vehicle;
b is a front perspective view of the vehicle from
a is a top view of
b is a top view of the vehicle from
c is a top view of the vehicle from
d is an enlarged side view of the vehicle from
e is an enlarged perspective view of the vehicle from
f is a front view of an exemplary wheel utilized in one embodiment of the present invention;
a is a front view of the vehicle from
b is a front view of the vehicle from
c is a perspective view of the vehicle from
d is a perspective view of the vehicle from
e is a perspective view of the vehicle from
f is a perspective view of the vehicle from
g is a perspective view of the vehicle from
h is a side view of the vehicle in the second orientation from
a is a top view of the vehicle from
b is a perspective view of the vehicle from
c is a perspective view of the vehicle from
d is a perspective view of the vehicle from
e is a perspective view of the vehicle from
f is a perspective view of the vehicle from
g is a top view of the vehicle in the second orientation from
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
While the invention is susceptible to embodiments in many different forms, there are shown in the drawings and will be described herein, in detail, the preferred embodiments of the present invention. It should be understood, however, that the present disclosure is to be considered an exemplification of the principles of the invention and is not intended to limit the spirit or scope of the invention, claims or the embodiments illustrated. This disclosure first discusses general principles along with vehicle components and dynamics relevant to the present invention and capabilities thereof. A disclosure of vehicles in accordance to illustrative embodiments follows.
A side rollover or barrel roll in various types of vehicles may result from a quick change in direction and a combination of enough momentum and high enough center of gravity. Typically vehicles that rollover may not roll back to their original orientation (roll back onto four wheels) due to various reasons including the location of the center of gravity, the design of a vehicle's body and/or lack of momentum. Aside from stunt shows or similar entertainment, side rollovers are typically not desirable in vehicles other than toys.
Conversely, in toy vehicles, stunts like side rollovers add play value and in particular rollovers on command may be desirable and further enhanced when combined with a vehicle chassis that facilitates wheel to surface contact in both a first orientation and a second orientation where the vehicle is upside down relative to the first orientation. Therefore, a toy vehicle having a center of gravity that can shift side to side while maintaining an equidistant vertical position relative to a surface in more than one orientation allows for controlled or predictable side rollovers.
Taking these principles into account and now referring to
While a typical, single section chassis has the potential to rollover, the two section chassis and pivot mechanism 25 of vehicle 10 facilitate the capability to shift the vehicle 10 center of gravity 30 during a turn or sharp change in direction to increase rollover capability. This may enable the vehicle 10 to roll over and about a central axis while in motion and at or above a rollover speed utilizing the pivot point or rollover point created at edge 32 of one of the wheels 35 while turning (further described below). The rollover speed is a speed great enough for the momentum and weight of the vehicle 10 to roll the vehicle 10 as the pivot mechanism 25 rotates the front section 15 to shift the weight distribution of the vehicle 10 which adjusts the positioning of the center of gravity 30 relative to the positioning of the wheels 35 on the outer side of a turn.
As mentioned above, an embodiment of the invention described herein also utilizes a modified wheel shape for wheels 35 to achieve a rollover movement. Continuing to refer to
Referring now to
The vehicle 110 may perform all of its movements without user control where the vehicle 110 responds to external factors, such as objects or terrain, to cause movements utilizing the components of the vehicle 110. Alternatively, the vehicle 110 may be controlled utilizing a variety of control systems including radio or remote control utilizing a transmitter/receiver pair and/or on-vehicle switches and/or sensors utilizing interactive preprogrammed content. The components of the vehicle 110 provide for a variety of movements and actions. One such example of a movement is a rollover movement where the vehicle 110 rolls about a central axis 137 while in motion (further described below). During the rollover movement the vehicle 110 may roll between a first orientation 134 and a second orientation 135 further defined to include the vehicle rolling over from the first orientation 134 to the second orientation 135 or the second orientation 135 to the first orientation 134. Perpendicular reference arrow 138 is included in the figures herein to assist in illustrating vehicle 110 positioning during movements. While the pivot mechanism 125 in this embodiment is motorized and rotates about axis 136, the invention may also utilize different pivot mechanism embodiments including a non-motorized pivot or a free pivot.
Continuing to refer to
Now additionally referring to
As mentioned above, the components included in the vehicle 110 facilitate movements including the rollover movement where the vehicle 110 rolls over and about axis 137 while in motion and at or above a rollover speed in accordance with user input. The rollover speed is a speed great enough to direct the center of gravity of the vehicle 110 to roll the vehicle 110 about axis 137 when a force (for example, the friction force created when the first section 115 turns to create a frictional pivot point at edge 198 of the raised tread 132 and a surface) acts against the direction of motion of the vehicle 110 to result in the rollover movement described herein. Rotating the pivot mechanism 125 shifts the weight distribution of the vehicle 110 which adjusts the center of gravity position relative to the wheels on the outer side of a turn during the initial stages of the rollover movement. Thus the center of gravity is positioned substantially in line with the pivot point at edge 198. When the vehicle 110 is moving at a speed below the rollover speed and the pivot mechanism 125 is activated, the vehicle 110 responds with left and right turns in accordance to rotation of the pivot mechanism 125. When the speed of the vehicle is at or above the rollover speed, activating the pivot mechanism 125 to turn the first section 115 far enough to create a pivot point at the edge 198 of the raised tread 132 relative to a surface (and thereby adjusting the positioning of the vehicle 110 center of gravity relative to the edge 198) will initiate the rollover movement illustrated in
Optionally, an orientation (described further below) sensor may determine vehicle 110 orientation relative to the surface to simplify user interface by converting user inputs to a user's first person perspective to direct vehicle 110 movements and execute the rollover movement in both the first orientation 134 and second orientation 135. Operation in multiple orientations including the first orientation 134 and second orientation 135 is further enabled by the wheels vertically clearing the vehicle 110 chassis and the vehicle housing as described above. It is also important to note that while the rollover movement is illustrated above with the first section 115 leading in a left turn while the vehicle 110 is moving in the first orientation 134, the vehicle 110 may execute the rollover movement while moving in other orientations and directions including starting in either the first orientation 134 or second orientation 135 and/or while moving in either a forward or reverse direction and/or while making left or right turns.
Referring now to
As mentioned above, a pivot mechanism utilized in the present invention may have different embodiments utilizing various pivots including a motorized pivot, a non-motorized pivot or a free pivot. Another illustrative embodiment of the present invention utilizing a non-motorized pivot is now discussed.
Referring now to
The vehicle 310 may perform all of its movements without user control where the vehicle 310 responds to external factors, such as objects or terrain, to cause movements utilizing the components of the vehicle 310. Alternatively, the vehicle 310 may be controlled utilizing a variety of control systems including radio or remote control utilizing a transmitter/receiver pair and/or on-vehicle switches and/or sensors utilizing interactive preprogrammed content. The vehicle's 310 components may provide for a variety of movements and actions. One such example of a movement is a rollover movement where the vehicle 310 rolls about a central axis 342 while in motion (further described below). During the rollover movement the vehicle 310 may roll between a first orientation 340 and a second orientation 345 further defined to include the vehicle 310 rolling over from the first orientation 340 to the second orientation 345 or the second orientation 345 to the first orientation 340. Perpendicular reference arrow 343 is included in the figures herein to assist in illustrating vehicle 310 positioning.
Continuing to refer to
Now additionally referring to
Additionally, the pivot mechanism 325 may optionally utilize a capability to assist with vehicle control, for example the utilization of magnetism. A first magnet 385 may be positioned on one of the flanges 365 and a second magnet 390 may be positioned on a flange 395 extending from the extension 375 such that the polarities attract one another. Appropriate magnet strengths may be used to provide an appropriate level of magnetism to assist in maintaining a consistent and linear relationship between the first section 315 and second section 320 while moving which is more consistent than a free pivot without magnetism provides. Further, the level of magnetism is less than that of the motor forces directing steering (described below) such that the magnetism does not prevent turning altogether but rather facilitates suppressed pivoting of the pivot mechanism 325 when user inputs direct the vehicle 310 to turn. FIG. Sf further illustrates a preferred design of the wheels 329, wheel 330 and wheel 332 with the raised tread 335, rounded tapered profile 336 and an edge 402.
As mentioned above, the components included in the vehicle 310 may facilitate movements including the rollover movement where the vehicle 310 rolls about axis 342 while in motion and at or above the rollover speed in accordance with user input. Adjusting the power distribution to the motors 346 while the vehicle is in motion may facilitate steering as rotation of the first wheel 330 and/or second wheel 332 increases or decreases in accordance thereto. In this embodiment, the rollover speed is a speed great enough to direct the center of gravity of the vehicle 310 to roll the vehicle 310 about axis 342 when a force (for example, the friction force created when the first section 315 turns to create a pivot point at edge 402 of the raised tread 335 and a surface 382) acts against the direction of motion of the vehicle 310 to result in the rollover movement described herein. Powering the first wheel 330 or second wheel 332 enough to overcome the level of magnetism in the pivot mechanism 325 may direct a turn and shift the weight distribution of the vehicle 310 which adjusts the positioning of the center of gravity relative to the positioning of the wheels on the outer side of a turn during the initial stages of the rollover movement. Thus, the center of gravity is positioned substantially in line with the pivot point at edge 402. As described above, when vehicle speed is below the rollover speed, the vehicle 310 may respond with left and right turns in accordance to the power distribution to each motor 346. When the vehicle speed is at or above the rollover speed, adjusting power to the first wheel 330 and/or second wheel 332 may initiate the rollover movement when the first section 315 turns enough to create a pivot point at the edge 402 of the raised tread 335 relative to a surface (and thereby adjusting the positioning of the vehicle 310 center of gravity relative to the edge 402) will initiate the rollover movement illustrated in
Optionally, an orientation sensor (described further below) determines vehicle 310 orientation relative to the surface to simplify user interface and control by converting user inputs to a user's first person perspective to direct vehicle 310 movements and execute the rollover movement in both the first orientation 340 and second orientation 345 and while moving in both directions. Operation in multiple orientations including the first orientation 340 and second orientation 345 is further enabled by the wheels vertically clearing the vehicle 310 chassis and the vehicle housing as described above. It is also important to note that while the rollover movement is illustrated above with the first section 315 leading in a left turn while the vehicle 310 is moving in the first orientation 340, the vehicle 310 may execute the rollover movement while moving in other orientations and directions including starting in either the first orientation 340 or second orientation 345 and/or while moving in either a forward or reverse direction and/or while making left or right turns. Referring now to
Further, in an illustrative embodiment, an exemplary vehicle may include a capability to direct steering via a pivot mechanism and a two section chassis.
Additionally, in another illustrative embodiment, an exemplary vehicle includes a capability to direct a controlled rollover movement utilizing a capability to direct steering and a pivot mechanism and two section chassis.
In yet another illustrative embodiment, an exemplary vehicle also may include a capability to steer the vehicle with preprogrammed movements utilizing switches and/or sensors included on the vehicle.
In yet another illustrative embodiment, an exemplary vehicle may include a capability to trigger a rollover movement utilizing a capability to steer the vehicle utilizing switches and/or sensors included on the vehicle.
From the foregoing and as mentioned above, it will be observed that numerous variations and modifications may be effected without departing from the spirit and scope of the novel concept of the invention. It is to be understood that no limitation with respect to the specific methods and apparatus illustrated herein is intended or inferred.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
The present application claims priority to U.S. Application No. 61/307,904 filed on Aug. 29, 2011 entitled “Toy Vehicle with Rollover Stunt Movements” and to U.S. application Ser. No. 13/597,443 filed on Aug. 29, 2012 entitled “Toy Vehicle with Rollover Stunt Movements”, now U.S. Pat. No. ______ B2, which issued on ______, 2015; the disclosures of which are incorporated in their entirety by reference herein.
Number | Date | Country | |
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61307904 | Feb 2010 | US |
Number | Date | Country | |
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Parent | 13597443 | Aug 2012 | US |
Child | 14800842 | US |