The present invention relates to remotely controlled vehicles and, in particular, to remotely controlled vehicles with multiple motors that can drive and execute stunts, including rolls or tumbles, in multiple driving positions or orientations.
Remotely controlled vehicles, which are also referred to as remote control (“RC”) vehicles, are well known and commonly used by children and adults for entertainment. RC vehicles are often battery powered and may take the form of cars, trucks, boats, planes, or any other type of vehicle. Moreover, conventional RC vehicles often drive forwards or backwards and can either drive straight or turn. New features that add entertainment value to an RC vehicle or enhance performance of an RC vehicle are continually desired.
According to at least one example embodiment of the present invention, a remotely controlled toy vehicle includes a front assembly, a rear assembly, a drive mechanism, and a roll mechanism. The front assembly and the rear assembly each include at least one wheel and the drive mechanism includes a drive motor configured to drive at least one of the at least one wheel of the front assembly and the at least one wheel of the rear assembly. The roll mechanism includes a roll motor configured to roll one of the front assembly and the rear assembly with respect to the other of the front assembly and the rear assembly.
According to other example embodiments of the present invention, a remotely controlled toy vehicle includes a first wheel assembly, a second wheel assembly, a drive mechanism, and a main body that includes a tumbling mechanism. The drive mechanism is configured to drive at least one of the first wheel assembly and the second wheel assembly. The main body is disposed between and coupled to the first wheel assembly and the second wheel assembly. The tumbling mechanism is configured to roll the first wheel assembly with respect to the second wheel assembly. In at least some of these embodiments, the drive mechanism is disposed in the second wheel assembly and operable to propel the remotely controlled vehicle regardless of an orientation of the first wheel assembly with respect to the second wheel assembly.
Additionally or alternatively, the main body may include a first portion coupled to the first wheel assembly and a second portion coupled to the second wheel assembly. In at least some of these embodiments, the first wheel assembly is swivably coupled to the first portion and may be swiveled to steer the remotely controlled vehicle. Still further, in some of these embodiments, the second wheel assembly is fixed to the second portion with respect to a longitudinal axis of the remotely controlled vehicle and the first wheel assembly is fixed to the first portion with respect to the longitudinal axis so that, in rolling the first wheel assembly, the tumbling mechanism rolls the first wheel assembly and the first portion with respect to the second wheel assembly and the second portion.
Like reference numerals have been used to identify like elements throughout this disclosure.
A remotely controlled toy vehicle (RC vehicle) is presented herein. Generally, the RC vehicle includes two wheel assemblies that are each configured to roll or tumble about a longitudinal axis (i.e., an axis passing through the front and back of the vehicle). That is, the wheel assemblies can roll with respect to each other (roll in terms of yaw, pitch, and roll, as opposed to rolling along a surface, which the wheel assemblies can also do). Moreover, in at least some embodiments, the RC vehicle includes a roll or tumbling mechanism that is configured to cause a front assembly of the RC vehicle (which includes a first wheel assembly) to roll about the longitudinal axis of the RC vehicle with respect to a rear assembly of the RC vehicle (which includes a second wheel assembly). Consequently, the RC vehicle can provide entertaining driving patterns and execute a variety of entertaining stunts, such as barrel rolls, flips, and spins (i.e., 180s).
The RC vehicle may also include a drive mechanism that is configured to propel the RC vehicle along a surface (i.e., pavement, grass, sand, etc.) regardless of the orientation of the wheel assemblies. In fact, the wheel assemblies may include substantially hemispherical outer edges to ensure the RC vehicle can drive when the wheel assemblies are in various angular orientations with respect to the support surface on which the RC vehicle is traveling. Consequently, the RC vehicle may continue to drive or travel as the wheel assemblies rotate and may seamlessly transition between driving and executing stunts, such as barrel rolls and 180 s.
Now referring to
Collectively, the first wheel assembly 110 and the first portion 310 may be referred to as a first or front assembly 102 of the RC vehicle 100. Similarly, the second wheel assembly 210 and the second portion 340 may be collectively referred to as a second or rear assembly 104 of the RC vehicle 100. However, it is to be understood that the RC vehicle 100 can drive in either direction D3 or direction D4 and, thus, designations of “front” or “rear” may simply be used for clarity. For example, if the RC vehicle 100 is driving in direction D4, the rear assembly 104 may be the front of the RC vehicle 100 (or the RC vehicle 100 may be considered to be moving in reverse).
Generally, the front assembly 102 and the rear assembly 104 are each individually rotatable about a longitudinal axis A1 extending through the vehicle (i.e., in the directions denoted by arrow D1). That is, the front assembly 102 and the rear assembly 104 are rotatable about the longitudinal axis A1 with respect to each other. More specifically, the second portion 340 of the main body 300 is rotatably coupled, at the rotation joint 302, to the first portion 310 of the main body 300 so that the second portion 340 can rotate about the longitudinal axis A1 with respect to the first portion 310. Meanwhile, wheel assembly 110 and wheel assembly 210 are coupled to the main body 300 in a manner that prevents roll rotation (i.e., rotation about axis A1) of wheel assembly 110 and wheel assembly 210 with respect to the main body 300.
In particular, in the depicted embodiment, the first wheel assembly 110 cannot rotate about the longitudinal axis A1 with respect to the first portion 310 of the main body 300 and the second wheel assembly 210 cannot rotate about the longitudinal axis A1 with respect to the second portion 340 of the main body 300. Consequently, the first wheel assembly 110 rotates about longitudinal axis A1 (i.e., in the directions denoted by arrow D1) with the first portion 310 of the main body 300 and the second wheel assembly 210 rotates about longitudinal axis A1 (i.e., in the directions denoted by arrow D1) with the second portion 340 of the main body 300.
That being said, in at least some embodiments, wheel assembly 110 may be able to move or rotate with respect to the first portion 310 of the main body 300 without rotating about the longitudinal axis A1. For example, in the depicted embodiment, the first wheel assembly 110 is swivably coupled to the first portion 310 so that the first wheel assembly 110 can rotate, in in the directions denoted by arrow D2. That is, the first wheel assembly 110 can yaw about a vertical axis A2, as is described in further detail below in connection with
As is described in further detail below, the aforementioned couplings (i.e., the swivel coupling of the first wheel assembly 110 to the first portion 310 and the fixed coupling of the second wheel assembly 210 to the second portion 340) may allow the first wheel assembly 110 to be used for steering while the second wheel assembly 210 to be used to power or propel the RC vehicle 100. However, in other embodiments, other couplings may be utilized while still allowing similar functionality. For example, in some embodiments, the second wheel assembly 210 may move or rotate about a yaw axis (parallel to axis A2) with respect to the second portion 340 of the main body 300. As another example, wheel assemblies 110 and 210 may each be rotatable about pitch axes (i.e., axes perpendicular to both axes A1 and A2) to allow for vertical movement of wheel assemblies 110 and 210 with respect to the main body 300 (i.e., to provide shocks or a shock-like movement).
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Additionally, the controller 400 may include a booster button 410 and secondary buttons 406. The booster button 410 may switch the vehicle 100 from a normal operating mode to a “boosted mode.” In the boosted mode, the vehicle 100 may be able to travel at faster speeds and perform additional stunts. For example, in the boosted mode, a speed governing function may be disabled. The secondary buttons 406 may provide different functions for the different modes. For example, when the booster button 410 is not actuated, the secondary buttons 406 may server as trim buttons to allow a user to adjust the alignment of the first assembly 102 with respect to the second assembly 104. Then, when the booster button 410 is actuated (i.e., depressed), the secondary buttons may be actuated to cause the RC vehicle 100 to move through predetermined paths, such as a 180 degree turn or a 90 degree turn.
Moreover, when the booster button 410 is depressed, the front assembly 102 may be free to roll with respect to the rear assembly 104. More specifically, when the booster button 410 is depressed, a roll mechanism included in the main body 300 may be free to spin or roll, as is described in further detail below. Depending on the grip and position of the first assembly 102 and the second assembly 104, this spinning will cause either the first portion 310 or the second portion 340 to roll or tumble, about the longitudinal axis A1, with respect to the other portion of the main body 300, as is also described in further detail below. Consequently, during operation, the RC vehicle 100 may move from a first driving position P1 to another driving position.
Now referring to
More specifically, wheel 160 and wheel 180 are mounted on hub 130 while wheel 260 and 280 are mounted on hub 230. Hub 130 includes a main or mounting portion 132 and a neck 134. The mounting portion 132 is configured to receive wheel 160 and wheel 180 on opposite sides thereof (i.e., wheel 160 and wheel 180 are mounted on an axle 112 extending through the mounting portion 132, which is shown in
Similarly, hub 230 includes a main or mounting portion 232 and a neck 234. The mounting portion 232 is configured to receive wheel 260 and wheel 280 on either side thereof (i.e., wheel 260 and wheel 260 are mounted on an axle 212 extending through the mounting portion 232, which is shown in
In
That being said, due, at least in part, to the similarity of the top and bottom of the RC vehicle 100, the RC vehicle 100 can operate (i.e., drive and execute stunts) in substantially the same manner regardless of the position or orientation of the first assembly 102 and the second assembly 104. That is, the RC vehicle 100 may drive with the front assembly 102 and/or the rear assembly 104 in nearly any orientation or position. For example, the RC vehicle 100 may drive with both the first assembly 102 and rear assembly 104 right side up (driving position P1) both the first assembly 102 and rear assembly 104 upside down (driving position P2, as shown in
Moreover, the RC vehicle 100 may also drive or travel along a support surface while the front assembly 102 and the rear assembly 104 (and, thus, the wheel assemblies 110, 210) are tilted or angled with respect to a support surface on which the RC vehicle 100 is traveling. That is, the RC vehicle may operate with wheel assembly 110 and wheel assembly 210 oriented at any roll angle. In fact, even if wheel assembly 110 and wheel assembly 210 are free to rotate about a roll axis (i.e., longitudinal axis A1) with respect to the main body 300 (instead of being fixed about the longitudinal axis A1 with respect to the main body 300, like the depicted embodiment), as may be the case in some embodiments, the RC vehicle 100 may still operate regardless of the angular orientation of wheel assembly 110 and wheel assembly 210. This continuous operation is supported, at least in part, by the shape of the wheels included in wheel assembly 110 and 210, which are described in connection with
In
With that in mind, wheel 160 includes a wheel hub 164 and a tread 162. The wheel hub 164 includes an annular portion 166 and a hemispherical portion 168. Meanwhile, the tread 162 is substantially annular and, thus, includes an inner wall 161 and an outer wall 163 that are substantially concentric. The outer wall 163 is configured to grip a support surface and, thus, may include various features that increase the coefficient of friction between the outer wall 163 and a support surface (i.e., treads). The inner wall 161 is configured to mate with an outer surface of the annular portion 166 of the wheel hub 164 so that the tread extends around the wheel hub 164.
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Turning next to
The drive mechanism 242 is included in an interior cavity 240 of the hub 230 of the second wheel assembly 210 and is configured to drive the wheels (wheel 260 and wheel 280) of the second assembly on an axle 212 that extends centrally through wheel assembly 210. More specifically, the drive mechanism 242 includes a drive motor 244 that is coupled to a gear train 246. The gear train 246 is coupled to the axle 212 and is configured, through well-known mechanical coupling methods to impart motion from the motor 244 to the axle 212. The axle 212 is fixedly coupled to wheel 260 and wheel 280 and, thus, when the axle 212 is driven by motor 244, the axle 212 rotationally drives wheels 260 and 280 so that wheels 260 and 280 engage and rotate against a surface to create a driving or propelling force for the RC vehicle 100.
In this particular embodiment, the RC vehicle 100 only includes a drive mechanism 242 in the second wheel assembly 210 and, thus, the RC vehicle may be referred to as a rear-wheel drive RC vehicle (despite the RC vehicle 100 also being able to dive with the rear assembly 210 as the front of the RC vehicle 100). However, in other embodiments, the RC vehicle 100 may include front-wheel drive or four-wheel drive. That is, another drive mechanism may be included in the interior cavity 140 of the first wheel assembly, either in place of or in addition to the drive mechanism 242 included in the second wheel assembly 210.
Still referring to
The nut 382 is fixedly coupled to the axle 380 and the first portion 310 of the main body 300. Meanwhile, the axle 380 is configured to be driven, either clockwise or counter-clockwise, by the roll motor 372 (via the gear train 378, which is fixedly coupled to the second portion 340 of the main body 300). Consequently, when the motor 372 imparts motion to the gear train 378, the gear train 378 imparts rotational motion to axle 380 that may rotate the first assembly 102 (via the nut 382) with respect to the second assembly 104. That is, activation of the roll motor 370 causes the first assembly 102 to roll about the longitudinal axis A1 (the first wheel assembly 110 and the first portion 310 both rotate about axis A1, since the first wheel assembly 110 is coupled to the first portion 310 in a manner that prevents roll rotation of the wheel assembly 110 with respect to the first portion 310). Alternatively, based on the grip and the position of assemblies 102 and 104, rotation of the axle 380 may rotate the second assembly 104 with respect to the first assembly 102. In other words, in at least some instances, rotational motion of the axle 380 may create a torque that drives the entire second portion 340 of the main body 300 (together with wheel assembly 210) around the axle 380.
Still referring to
More specifically, and now referring to
To permit yaw movement of the first wheel assembly 110, the neck 134 of the first wheel assembly is coupled to the receptacle 312 of the first portion 310 of the main body 300 via a swivel mechanism 330 (see
More specifically, when the RC vehicle 100 is in a normal operating mode, the roll mechanism 370 may be configured to rotate the front assembly 102 so that the wheel assembly 110 swivels about axis A2 with respect to the first portion 310 of the main body 300 without rolling about axis A1. For example, when the RC vehicle 100 is in a normal operating mode, the roll mechanism 370 may only be configured to rotate the axle 380 approximately 35 degrees in either direction. This rotation may cause the wheel assembly 110 to swivel about axis A2 without rolling about axis A1. By comparison, when the RC vehicle 100 is operating in the boosted mode, the roll mechanism 370 may be free to rotate the axle 380 through any number of rotations in either direction (i.e., 360 degrees or more clockwise or counter-clockwise). This may create more exciting driving scenarios, since the RC vehicle 100 may roll into turns instead of simply steering into turns. In fact, buttons 406 may be preprogrammed to cause the RC vehicle 100 to roll into a 180 degree turn or a 90 degree turn when the RC vehicle 100 is in the boosted mode.
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Now referring to
The transmitter/receiver 802 is generally configured to communicate with the transmitter/receiver 420 so that the controller 400 can drive the RC vehicle 100 and receive feedback from the RC vehicle (i.e., feedback from the wiper mechanism 384 to determine the steering orientation of the vehicle). For example, the transmitter/receiver 420 and transmitter/receiver 802 may be connected through a wireless communication channel or protocol, such as BLUETOOTH®, or any other known form of wireless communication feasible between a controller and a RC vehicle. The processor 804 is connected to the mechanisms included in the vehicle 100 (i.e., the roll mechanism 370, and the drive mechanism 242) and is generally configured to control these mechanisms based on signals received from the controller 400 (at the transmitter/receiver 802) and/or instructions stored in memory 806. The battery 808 is generally configured to supply power to any mechanisms or components in the vehicle 100 that require power (i.e., the processor 804, the roll mechanism 370, and the drive mechanism 242).
More specifically, although diagram 800 shows a signal block 802 for the processor, it should be understood that the processor 802 may represent a plurality of processing cores, each of which can perform separate processing. Meanwhile, memory 806 may include random access memory (RAM) or other dynamic storage devices (i.e., dynamic RAM (DRAM), static RAM (SRAM), and synchronous DRAM (SD RAM)), for storing information and instructions to be executed by processor 802. The memory 806 may also include a read only memory (ROM) or other static storage device (i.e., programmable ROM (PROM), erasable PROM (EPROM), and electrically erasable PROM (EEPROM)) for storing static information and instructions for the processor 802. Although not shown, the vehicle 100 may include a bus or other communication mechanism for communicating information between the processor 802 and memory 806
The processor 802 may also include special purpose logic devices (i.e., application specific integrated circuits (ASICs)) or configurable logic devices (i.e., simple programmable logic devices (SPLDs), complex programmable logic devices (CPLDs), and field programmable gate arrays (FPGAs)), that, in addition to microprocessors and digital signal processors may individually, or collectively, are types of processing circuitry. The processing circuitry may be located in one device or distributed across multiple devices.
The controller 802 performs a portion or all of the processing steps required to control the RC vehicle 100 in response to instructions received at transmitter/receiver 802 and/or instructions contained in a memory 806. Such instructions may be read into memory 806 from another computer readable medium. One or more processors in a multi-processing arrangement may also be employed to execute the sequences of instructions contained in memory 806. In alternative embodiments, hard-wired circuitry may be used in place of or in combination with software instructions. Thus, embodiments are not limited to any specific combination of hardware circuitry and software.
Put another way, the vehicle 100 includes at least one computer readable medium or memory for holding instructions programmed according to the embodiments presented, for containing data structures, tables, records, or other data described herein. Examples of computer readable media are compact discs, hard disks, floppy disks, tape, magneto-optical disks, PROMs (EPROM, EEPROM, flash EPROM), DRAM, SRAM, SD RAM, or any other magnetic medium, compact discs (i.e., CD-ROM), or any other optical medium, or any other medium from which a computer can read.
Although the disclosed inventions are illustrated and described herein as embodied in one or more specific examples, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the scope of the inventions. In addition, various features from one of the embodiments may be incorporated into another of the embodiments. Accordingly, it is appropriate that the invention be construed broadly and in a manner consistent with the scope of the disclosure.
Additionally, it is to be understood that terms such as “left,” “right,” “top,” “bottom,” “front,” “end,” “rear,” “side,” “height,” “length,” “width,” “upper,” “lower,” “interior,” “exterior,” “inner,” “outer” and the like as may be used herein, merely describe points or portions of reference and do not limit the present invention to any particular orientation or configuration. Further, terms such as “first,” “second,” “third,” etc., merely identify one of a number of portions, components and/or points of reference as disclosed herein, and do not limit the present invention to any particular configuration or orientation.
This application claims the benefit of U.S. Provisional Patent Application No. 62/459,493, filed Feb. 15, 2017, entitled “Remotely Controlled Toy Vehicle,” the entire disclosure of which is incorporated by reference herein.
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MightMouse74Reviews, The Dark Night Rises U-Command Bat-Pod With Remote Control by Thinkway Toys Toy Review!!, Jul. 26, 2012 https://www.youtube.com/watch?v=4iplKlbFatU Whole Video. |
Number | Date | Country | |
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20180229135 A1 | Aug 2018 | US |
Number | Date | Country | |
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62459493 | Feb 2017 | US |