A ride-on vehicle is provided that has drive and spin functionalities. The ride-on vehicle comprises a first motor for a first drive wheel, and a second motor for a second drive wheel. The vehicle has a steering wheel having a go selector and a spin selector. A sensor obtains an output of the angular rotation location of the steering wheel. A controller is electrically connected to the first and second motors, the go selector, the spin selector, and the steering wheel sensor, wherein engaging the go selector and turning the steering wheel causes the vehicle to move forward, left or right, depending on the angular location of the steering wheel, and wherein engaging the spin selector and turning the steering wheel causes the vehicle to spin left or spin right, depending on the angular location of the steering wheel. The vehicle may also be controlled remotely by a remote control.

A detachable seat assembly, including: a handle member, a seat member and a saddle member, the handle member including a mounting portion at a bottom side thereof, the mounting portion including an inner threaded hole at a front side thereof and a buckling member; the seat member and the handle member being detachably connected, the seat member including a mounting hole within which the mounting portion is inserted, the seat member further including a knob and a first hole, the knob including a handle and a threaded section, the threaded section being screwed to the inner threaded hole, the buckling member being disposed through the first hole; the saddle member being mounted on the handle member and the seat member.

An improved toy vehicle is disclosed herein. The toy vehicle includes a plurality of different modules that may be removably coupled to one another to provide a variety of different toy vehicles. The modules include at least a steering module, a gearbox module, and a main body module. The main body module may house any number of elastic members configured to drive a drive axle disposed within the gearbox module. The size and construction of the main body module chosen to be used may dictate how fast and how far the modular toy vehicle is capable of traveling across a support surface. The gearbox module may further include a crank that enables the elastic members to be wound and an actuator that actuates the wound elastic members to drive the toy vehicle. Finally, the steering module may be configured to direct the modular toy vehicle in a desired direction.

An improved toy vehicle is disclosed herein. The toy vehicle includes a plurality of different modules that may be removably coupled to one another to provide a variety of different toy vehicles. The modules include at least a steering module, a gearbox module, and a main body module. The main body module may house any number of elastic members configured to drive a drive axle disposed within the gearbox module. The size and construction of the main body module chosen to be used may dictate how fast and how far the modular toy vehicle is capable of traveling across a support surface. The gearbox module may further include a crank that enables the elastic members to be wound and an actuator that actuates the wound elastic members to drive the toy vehicle. Finally, the steering module may be configured to direct the modular toy vehicle in a desired direction.

A floating magnetic vehicle and track toy for education and entertainment of users includes an annular plate that has an inside edge and an outside edge. A first rim, positioned adjacent to the inside edge, and a second rim, positioned adjacent to the outside edge, are coupled to and extend perpendicularly from the annular plate. A plurality of first magnets is coupled to the annular plate. The toy comprises a car that comprises a plurality of second magnets. The second magnets are positioned on the car to repel the first magnets to suspend the car above the annular plate. The first rim and the second rim are positioned on the annular plate to retain the car between the first rim and the second rim. The car is configured to be motivated around the annular plate by a pushing action of a user.

A floating magnetic vehicle and track toy for education and entertainment of users includes an annular plate that has an inside edge and an outside edge. A first rim, positioned adjacent to the inside edge, and a second rim, positioned adjacent to the outside edge, are coupled to and extend perpendicularly from the annular plate. A plurality of first magnets is coupled to the annular plate. The toy comprises a car that comprises a plurality of second magnets. The second magnets are positioned on the car to repel the first magnets to suspend the car above the annular plate. The first rim and the second rim are positioned on the annular plate to retain the car between the first rim and the second rim. The car is configured to be motivated around the annular plate by a pushing action of a user.

A ridable kart having a front portion rotatably coupled to a rear portion. The front portion includes an inner surface that is adjacent to an outer cover portion and the two surfaces move relative to one another. The outer cover portion includes window portions or openings through which a portion of the inner surface is visible. The inner surface includes a visual feature that is visible through the window portions and the visual features moves relative to the window portions when the front portion rotates relative to the rear portion.

A ridable kart having a front portion rotatably coupled to a rear portion. The front portion includes an inner surface that is adjacent to an outer cover portion and the two surfaces move relative to one another. The outer cover portion includes window portions or openings through which a portion of the inner surface is visible. The inner surface includes a visual feature that is visible through the window portions and the visual features moves relative to the window portions when the front portion rotates relative to the rear portion.

A family of toy cars includes a plurality of components, which cooperatively translate a motive force applied to a finger engagement structure into motion of the toy car in a horizontal plane. The toy car system includes a chassis, a body, a finger engagement structure, a pair of front wheels rotatably coupled to the chassis, and a pair of rear wheels rotatably coupled to the chassis. Each of the front pair of wheels may be coupled to the front suspension by a castered coupling. The toy car may include a steering linkage between the front wheels configured such that the front wheels turn in unison in response to the motive force applied to the toy car.

A family of toy cars includes a plurality of components, which cooperatively translate a motive force applied to a finger engagement structure into motion of the toy car in a horizontal plane. The toy car system includes a chassis, a body, a finger engagement structure, a pair of front wheels rotatably coupled to the chassis, and a pair of rear wheels rotatably coupled to the chassis. Each of the front pair of wheels may be coupled to the front suspension by a castered coupling. The toy car may include a steering linkage between the front wheels configured such that the front wheels turn in unison in response to the motive force applied to the toy car.